JP2017180610A - Sensor holding tool and fluid controller including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sensor holding tool capable of being easily and surely attached to a gas line even in a case of specification change and the like, and a fluid controller including the sensor holding tool.SOLUTION: A sensor holding tool 1 is configured to be mounted to a pair of hexagon socket head cap screws 18 for fixing a flow rate control instrument 10 to a joint 24. The sensor holding tool 1 includes: a base block 2 arranged on the pair of screws 18; a pair of hexagon pins 3 and a pair of screw 4 supporting the base block 2, inserted and fixed to a hexagon hole 18c of the pair of screws 18, and configured to fix the base block 2 to the screw 18; and a fixation screw 5 and a holding plate 6 fixed to the base block 2, and holding a thermocouple 16.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a sensor holder used in a fluid control device used in a semiconductor manufacturing apparatus or the like and a fluid control device including the sensor holder.

  Conventionally, a fluid control device including a plurality of gas lines has been proposed (see, for example, Patent Document 1). Each gas line has a plurality of fluid control devices and a plurality of joints, and a plurality of fluid control devices are connected to each other by attaching a plurality of fluid control devices to the upper surface of the plurality of joints, thereby supplying fluid. Is done.

JP 2002-349797 A

  By the way, when a gas that liquefies at room temperature is used in a semiconductor manufacturing process, a heater is attached to the gas line. In order to check whether the gas line is appropriately heated by the heater, a temperature sensor such as a thermocouple and a sensor holder for holding the temperature sensor are also attached to the gas line. And the sensor holder is designed according to the place to install.

  However, when a specification change or the like occurs during the manufacture of the fluid control device, the sensor holder must be designed again, which requires a lot of time and labor.

  Accordingly, an object of the present invention is to provide a sensor holder that can be easily and surely attached to a gas line even if there is a specification change or the like, and a fluid control device including the sensor holder.

  In order to solve the above-described object, a sensor holder according to one aspect of the present invention is a sensor holder attached to a hexagon socket head bolt for fixing a flow control device to a joint, and the hexagon socket head bolt A base block disposed on the base block, and a fixing portion for supporting the base block and being inserted into and fixed to a hexagon socket of the hexagon socket head cap screw, and fixing the base block to the hexagon socket head cap bolt; A sensor holding unit that is fixed to the base block and holds the temperature sensor.

  The fixing portion has a screw having a head and a shank in which a male screw is formed, a through-hole having a female screw provided on the inner periphery, and a projecting portion protruding inward, so that the hexagon socket head bolt A cylindrical member having an end portion inserted into the hexagonal hole, the shank of the screw is inserted into the through hole of the cylindrical member, and the female screw of the screw is inserted into the cylindrical member. By screwing into the female screw, the projecting portion of the tubular member may be pushed by the tip of the shank, and the end portion of the tubular member may be expanded.

  The cylindrical member may have a hexagonal outer shape.

  The sensor holding portion includes a fixing bolt screwed to the base block, a welding hole into which a thermocouple as the temperature sensor is inserted and welded, and a notch in which a shank of the fixing bolt can be inserted and removed. And a holding plate on which are formed.

  The base block is formed with a mounting hole into which the screw and the cylindrical member are inserted, a screwing hole into which the fixing bolt is screwed, and the insertion hole into which the thermocouple is inserted. Also good.

  Moreover, you may provide the sensor holding tool as described in the above attached to the hexagon socket head cap screw for fixing the fluid control device to the joint.

  Further, the fluid control device is a flow control device comprising a main body part for controlling the flow rate of gas, a primary side joint and a secondary side joint connected to the joint, and the hexagon socket head cap bolt, The hexagon socket head cap screw may be used to fix the secondary side joint to the joint.

  In addition, a leak port for detecting a gas leak is formed in the secondary side joint, and a tip of a thermocouple that is the temperature sensor is inserted into the leak port.

  According to the present invention, it is possible to provide a sensor holder that can be easily and surely attached to a gas line and a fluid control device including the sensor holder even if there is a specification change or the like.

The side view of the fluid control apparatus with which the sensor holder concerning this embodiment was equipped is shown. The side view of the flow control apparatus with which the sensor holder which concerns on this embodiment was mounted | worn is shown. The top view of the flow control apparatus with which the sensor holder was mounted | worn is shown. Sectional drawing of the flow control apparatus along the IV-IV line | wire of FIG. 2 is shown. (A) shows the top view of a sensor holder, (b) shows explanatory drawing of the mounting method of a sensor holder. (A) shows the top view of a base block, (b) shows the side view of a base block. (A) shows a plan view of the hexagonal pin, (b) shows a side view of the hexagonal pin, (c) shows a bottom view of the hexagonal pin, and (d) shows VIId- of (a). Sectional drawing of the hexagonal pin along the VIId line is shown. The top view of a holding plate is shown.

  A fluid control device 20 including a sensor holder 1 according to an embodiment of the present invention will be described with reference to the drawings. In the following description, the top and bottom are the top and bottom of FIG.

  FIG. 1 shows a side view of a fluid control device 20 including a sensor holder 1.

  The fluid control device 20 includes a base 21, a plurality (only one is shown in FIG. 1) of gas lines 22, and a gas out manifold 23. Each gas line 22 includes a plurality of joints 24 and a plurality of fluid control devices 10, 25 to 30. The plurality of joints 24 are arranged in a line on the base 21 and are fixed to the base 21 with bolts (not shown).

  The plurality of fluid control devices 10, 25 to 30 include a flow control device (for example, a mass flow controller) 10, an automatic valve (for example, a fluid-driven automatic valve) 25 to 28, and a manual regulator (pressure reducing valve) 29. , And a filter 30. The fluid control devices 25 to 30 are respectively connected to the joint 24 and the gas out manifold 23 by bolts 31 (only one bolt 31 is provided with a reference number for simplification of the drawing).

  Then, the process gas passes through the fluid control devices 10, 25 to 30, the plurality of joints 24, and the gas out manifold 23, and is supplied to a chamber (not shown).

  Next, the flow control device 10 to which the sensor holder 1 is attached will be described.

  FIG. 2 shows a side view of the flow control device 10 to which the sensor holder 1 according to this embodiment is mounted. FIG. 3 shows a plan view of the flow control device 10 to which the sensor holder 1 is mounted. FIG. 4 shows a cross-sectional view of the flow control device 10 taken along line IV-IV in FIG.

  As shown in FIG. 2, the flow control device 10 includes a body 11, a cover 12, a flow sensor (not shown), a control unit (not shown), a main body 13 mainly including a flow control mechanism (not shown), and the body 11. The primary side joint 14 and the secondary side joint 15 which were connected are provided. Here, the upstream side of the fluid flow with respect to the body 11 is a primary side, and the downstream side is a secondary side.

  The body 11 is formed with a flow path through which a fluid passes. The cover 12 covers the body 11, a flow rate sensor (not shown), a control unit (not shown), and a flow rate control mechanism (not shown).

  The primary side joint 14 is provided on the primary side with respect to the body 11, and the secondary side joint 15 is provided on the secondary side with respect to the body 11. Since the primary side joint 14 and the secondary side joint 15 have the same shape in the case of the present embodiment, only the secondary side joint 15 will be described, and detailed description of the primary side joint 14 will be omitted. .

  The secondary side joint 15 has a stepped portion 15a and has a substantially rectangular parallelepiped shape, and includes four first bolt through holes 15b penetrating in the left-right direction in FIG. 2 and two second penetrating holes in the up-down direction in FIG. A bolt through hole 15c, a leak port 15d for detecting fluid leakage, a fluid flow path 15e, and an annular recess 15f are formed. A gasket (not shown) is inserted into the annular recess 15f, and the connecting portion between the secondary side joint 15 and the joint 24 is sealed. The lower end of the leak port 15d opens to the annular recess 15f. When the connecting portion between the secondary side joint 15 and the joint 24 is not properly sealed by a gasket (not shown), the fluid flows into the leak port 15d, and the fluid detector detects the fluid leak.

  The first bolts 17 with hexagonal holes are passed through the first bolt through holes 15b, and the secondary joints 15 are fixed to the body 11 by screwing the first bolts 17 into the body 11. ing. A second bolt 18 with a hexagonal hole is passed through each second bolt through hole 15c.

  The second bolt 18 includes a head 18A and a shank 18B, and a hexagonal hole 18c is formed in the head 18A. The shank 18 </ b> B of the second bolt 18 is screwed into a joint 24 provided on the base 21. The sensor holder 1 is attached to the pair of second bolts 18.

  The primary side joint 14 is fixed to a joint 24 provided on the base 21 by a pair of third bolts 19 with hexagonal holes. In this manner, the primary side joint 14 and the secondary side joint 15 are fixed to the joint 24, whereby the flow control device 10 is fixed to the base 21.

  Next, the sensor holder 1 will be described with reference to FIGS.

  FIG. 5A shows a plan view of the sensor holder 1, and FIG. 5B shows an explanatory view of a mounting method of the sensor holder 1.

  As shown in FIG. 5, the sensor holder 1 includes a base block 2, a pair of hexagon pins 3, a pair of screws 4, a fixing bolt 5, and a holding plate 6. The pair of hexagonal pins 3 and the pair of screws 4 correspond to fixing portions, the hexagonal pins 3 correspond to cylindrical members, and the fixing bolts 5 and the holding plate 6 correspond to sensor holding portions.

  FIG. 6A shows a plan view of the base block 2, and FIG. 6B shows a side view of the base block 2.

  The base block 2 has a substantially rectangular parallelepiped shape, and as shown in FIGS. 2 to 4, the dimensions of the base block 2 are configured to fit within the step portion 15 a of the second joint 15 in a state where the base block 2 is attached to the second bolt 18. Yes. As shown in FIG. 6, the base block 2 is formed with a pair of mounting holes 2a, a screw hole 2b, and an insertion hole 2c. The pair of mounting holes 2 a are formed so as to correspond to the hexagonal holes 18 c of the second bolt 18. The insertion hole 2c is formed so as to correspond to the leak port 15d.

  7A shows a plan view of the hexagonal pin 3, FIG. 7B shows a side view of the hexagonal pin 3, FIG. 7C shows a bottom view of the hexagonal pin 3, and FIG. (D) has shown sectional drawing of the hexagonal pin 3 along the VIId-VIId line | wire of Fig.7 (a).

  The outer shape of the hexagonal pin 3 is a hexagonal cylindrical shape, and a through hole 3a penetrating in the vertical direction is formed. The hexagonal pin 3 is inserted into the mounting hole 2 a of the base block 2. The size of the outer shape of the horizontal section of the hexagonal pin 3 is configured to be slightly smaller than the size of the horizontal section of the hexagonal hole 18 c of the second bolt 18. An annular protrusion 3C that protrudes inward is provided at the center portion 3B in the vertical direction of the hexagonal pin 3, and an internal thread 3D is formed on the inner periphery of the annular protrusion 3C. A slit 3f is formed at a position corresponding to the vertex of the hexagon in the lower side portion 3E in the vertical direction of the hexagon pin 3. The diameter of the lower side portion 3E can be increased by the slit 3f. Further, the lower portion 3E is provided with a protruding portion 3G that protrudes inward from the annular protrusion 3C.

  As shown in FIG. 5, the screw 4 is a plus screw and has a head 4A and a shank 4B. An external thread 4C is formed on the shank 4B. By inserting the shank 4B of the screw 4 into the through hole 3a of the hexagonal pin 3 and screwing the male screw 4C of the screw 4 into the female screw 3D of the hexagonal pin 3, the protruding portion 3G of the hexagonal pin 3 is pushed by the tip 4D of the shank 4B. As a result, the lower side 3E of the hexagonal pin 3 is expanded.

  As shown in FIG. 5, the fixing bolt 5 is a hexagon socket head cap screw and includes a head 5 </ b> A and a shank 5 </ b> B. The shank 5 </ b> B of the fixing bolt 5 is screwed into the screwing hole 2 b of the base block 2.

  FIG. 8 shows a plan view of the holding plate 6.

  The holding plate 6 is a metal flat plate and has a substantially rectangular shape in plan view. A welding hole 6 a is formed in the holding plate 6. The thermocouple 16 is inserted into the welding hole 6a, the thermocouple 16 is welded to the holding plate 6, and the holding plate 6 and the thermocouple 16 are integrated. The holding plate 6 is formed with a notch 6b having a width smaller than the outer diameter of the head 5A of the fixing bolt 5 and larger than the outer diameter of the shank 5B of the fixing bolt 5. The shank 5B of the fixing bolt 5 can be relatively inserted into and removed from the notch 6b. The notch 6b opens to the upper side in FIG. 8, and is curved so as to approach the weld hole 6a as it goes upward. Further, the welding hole 6 a and the notch 6 b of the holding plate 6 are formed so as to correspond to the insertion hole 2 c and the screwing hole 2 b of the base block 2.

  Next, a method of mounting the sensor holder 1 on the flow control device 10 will be described with reference to FIG. The holding plate 6 and the thermocouple 16 are integrated in advance by passing the thermocouple 16 through the welding hole 6 a of the holding plate 6 and welding the thermocouple 16 to the holding plate 6.

  The base block 2 is placed on the head 18 </ b> A of a pair of second bolts 18 for fixing the secondary side joint 15 to the joint 24. At this time, the pair of mounting holes 2 a of the base block 2 are positioned on the hexagonal holes 18 c of the head 18 A of the pair of second bolts 18.

  Each hexagonal pin 3 is passed through each mounting hole 2a, and the lower side 3E of each hexagonal pin 3 is inserted into the hexagonal hole 18c of the head 18A of each second bolt 18. By inserting the shank 4B of the screw 4 into the through hole 3a of the hexagonal pin 3 and screwing the male screw 4C into the female screw 3D of the hexagonal pin 3, the lower side 3E of the hexagonal pin 3 is pushed and expanded by the tip 4D of the shank 4B. The outer surface 3H of the lower side portion 3E is pressed against the inner surface 18d that forms the hexagonal hole 18c. As a result, the hexagonal pin 3 is fixed to the second bolt 18. Then, the shank 4B of the screw 4 is screwed into the hexagonal pin 3 fixed to the second bolt 18, and the head 4A of the screw 4 comes into contact with the base block 2, so that the base block 2 becomes a pair of second It is fixed to the bolt 18.

  The tip of the thermocouple 16 is inserted into the insertion hole 2 c of the fixed base block 2 and inserted into the leak port 15 d of the secondary side joint 15. The fixing bolt 5 is screwed into the screwing hole 2b of the base block 2 through the notch 6b of the holding plate 6, and the holding plate 6 is tightly pressed by the head 5A of the fixing bolt 5 and the base block 2, so that the thermoelectric The pair 16 is fixed to the base block 2.

  The fixing bolt 5 is slightly loosened, the holding plate 6 is rotated around the weld hole 6a, and the shank 5B of the fixing bolt 5 is relatively extracted from the notch 6b of the holding plate 6, thereby causing the holding plate 6 and the thermoelectric The pair 16 can be removed from the base block 2.

  According to the sensor holder 1 described above, the base block 2 disposed on the pair of second bolts 18 for fixing the flow control device 10 to the joint 24 provided on the base 21, and the base block 2 are supported. A pair of hexagonal pins 3 and a pair of screws 4 for fixing the base block 2 to the second bolt 18, and a base block 2. A fixing bolt 5 for holding the thermocouple 16 and a holding plate 6 are provided.

  According to such a configuration, the sensor holder 1 can be attached to the second bolt 18 for fixing the flow rate control device 10 to the joint 24. Therefore, even if the specification of the fluid control device 20 is changed, the gas The sensor holder 1 can be attached to the line 22 easily and reliably.

  Further, by inserting the shank 4B of the screw 4 into the through hole 3a of the hexagonal pin 3 and screwing the male screw 4C of the screw 4 into the female screw 3D of the hexagonal pin 3, the protruding portion 3G of the hexagonal pin 3 is the tip of the shank 4B. The lower part 3E of the hexagon pin 3 is pushed and expanded by being pushed by 4D. According to this configuration, the outer surface 3H of the lower portion 3E of the hexagonal pin 3 is pressed against the inner surface 18d that forms the hexagonal hole 18c of the second bolt 18, thereby fixing the hexagonal pin 3 to the second bolt 18. be able to.

  Further, since the outer shape of the hexagonal pin 3 is a hexagonal cylinder and the second bolt 18 is the second bolt 18 with the hexagonal hole 18c, the contact area between the hexagonal pin 3 and the second bolt 18 can be increased. The hexagonal pin 3 can be firmly fixed to the second bolt 18.

  Further, the sensor holding part is formed with a fixing bolt 5 screwed to the base block 2, a welding hole 6a into which the thermocouple 16 is inserted and welded, and a notch 6b into which the shank 5B of the fixing bolt 5 can be inserted and removed. The holding plate 6 is provided. According to this configuration, the base block 2 is fixed to the pair of second bolts 18, and the holding plate 6 is attached to the base block 2 by the fixing bolt 5, and then the fixing bolt 5 is loosened slightly to cut the holding plate 6. The retaining plate 6 and the thermocouple 16 can be removed from the base block 2 by relatively extracting the shank 5B of the fixing bolt 5 from the notch 6b.

  The base block 2 is formed with a pair of mounting holes 2a into which the screws 4 and the hexagonal pins 3 are inserted, a screwing hole 2b into which the fixing bolt 5 is screwed, and an insertion hole 2c into which the thermocouple 16 is inserted. Yes. According to such a configuration, the sensor holder 1 can be mounted on the flow control device 10 simply by forming the pair of mounting holes 2 a corresponding to the positions of the pair of second bolts 18.

  Further, the pair of second hexagon socket head bolts 18 are used to fix the secondary side joint 15 to the joint 24, and the sensor holder 1 is attached to the second bolt 18. According to such a configuration, in the case of a fluid (gas) having a low boiling point, it is possible to detect the temperature of the fluid at a location where the temperature tends to decrease due to adiabatic expansion in a flow rate control mechanism (not shown).

  Further, the secondary joint 15 is formed with a leak port 15d for detecting gas leakage, and the tip of the thermocouple 16 is inserted into the leak port 15d, so that a hole for inserting the thermocouple 16 is newly formed. The temperature of the fluid can be detected without forming.

  In addition, this invention is not limited to the Example mentioned above. A person skilled in the art can make various additions and changes within the scope of the present invention.

  For example, in the above-described embodiment, the sensor holder 1 is mounted on the pair of second bolts 18 with hexagonal holes for fixing the secondary side joint 15, but the pair for fixing the primary side joint 14. You may attach to the 3rd volt | bolt 19 with a hexagon socket.

  Further, although the hexagonal pin 3 whose outer shape is a hexagonal cylindrical shape is used as the cylindrical member, the outer shape may be a triangular cylindrical shape or a cylindrical shape. Moreover, although the notch 6b of the holding plate 6 is formed, it may be simply a through hole. Moreover, although the temperature sensor was the thermocouple 16, a temperature measuring resistor etc. may be sufficient.

  Moreover, although the primary side coupling 14 and the secondary side coupling 15 were comprised so that it might be fixed to the coupling 24 by a pair of 1st, 2nd bolts 18 and 19, respectively, It may be a fixed configuration. In this case, only one mounting hole 2a is formed in the base block 2, and the base block 2 is fixed to the bolt by inserting the hexagonal pin 3 and the screw 4 into one mounting hole 2a.

DESCRIPTION OF SYMBOLS 1: Sensor holder 2: Base block, 2a: Mounting hole, 2b: Screwing hole, 2c: Insertion hole 3: Hex pin, 3a: Through hole, 3D: Female screw, 3E: Lower side part, 3G: Protrusion part 4 : Screw, 4A: Head, 4B: Shank, 4C: Male screw,
5: Fixing bolt 6: Holding plate, 6a: Weld hole, 6b: Notch 10: Flow control device 13: Main body part 14: Primary side joint 15: Secondary side joint, 15d: Leak port 16: Thermocouple 18: Second bolt, 18c: Hexagon socket
20: Fluid control device 21: Base 24: Joint

Claims (8)

A sensor holder mounted on a hexagon socket head cap screw for fixing a flow control device to a joint,
A base block disposed on the hexagon socket head cap screw;
A fixing portion for supporting the base block, being inserted and fixed in a hexagon socket of the hexagon socket head bolt, and fixing the base block to the hexagon socket socket bolt;
A sensor holding part fixed to the base block and holding the temperature sensor. The fixed part is
A screw having a head and a shank formed with a male screw;
A cylindrical member having a through hole provided with an internal thread on the inner periphery, having a protruding portion protruding inward and having an end inserted into the hexagonal hole of the hexagonal socket bolt,
By inserting the shank of the screw into the through-hole of the cylindrical member and screwing the female screw of the screw into the female screw of the cylindrical member, the protruding portion of the cylindrical member becomes the tip of the shank. The sensor holder according to claim 1, wherein the end portion of the cylindrical member is pushed and spread by being pushed by a portion.   The sensor holder according to claim 2, wherein the cylindrical member has a hexagonal cylindrical shape. The sensor holding unit is
A fixing bolt screwed to the base block;
The holding plate in which the welding hole in which the thermocouple which is the said temperature sensor is inserted and welded, and the notch which can insert / remove the shank of the said fixing bolt is provided. The sensor holder according to claim 1.   The base block is formed with a mounting hole into which the screw and the cylindrical member are inserted, a screwing hole into which the fixing bolt is screwed, and the insertion hole into which the thermocouple is inserted. Item 6. The sensor holder according to Item 5.   A fluid control apparatus comprising the sensor holder according to any one of claims 1 to 5, which is attached to a hexagon socket head bolt for fixing a fluid control device to a joint. The fluid control device is a flow control device comprising a main body part for controlling the flow rate of gas, a primary side joint and a secondary side joint connected to the joint, and the hexagon socket head cap screw,
The fluid control device according to claim 6, wherein the hexagon socket head cap screw is used to fix the secondary side joint to the joint. The fluid control device according to claim 7, wherein a leak port for detecting a gas leak is formed in the secondary side joint, and a tip of a thermocouple that is the temperature sensor is inserted into the leak port. .

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