JP2016205553A - Heat insulation cover and fluid control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat insulation cover capable of suppressing temperature fluctuation of a gas flowing in a gas line by airflow in a housing, and a fluid control device including the same.SOLUTION: A heat insulation cover 30 for covering a gas line 3 composed of a plurality of fluid control devices 7-9, 11, 12 fixed by joints 6, includes a side cover portion 31 having paired first to forth side wall portions 35A-38A kept into contact with both side faces of the joint 6 in a lateral direction of the gas line 3 and opposed to the plurality of fluid control devices 7-9, 11, 12 in the lateral direction, and first to forth upstream-side end wall portions 35B-38B disposed on end portions of the first to forth side wall portions 35A-38A, and an upper cover portion 32 disposed on an upper portion of the side cover portion 31.SELECTED DRAWING: Figure 3

Description

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

  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 using a gas that liquefies at room temperature, a planar heater is attached to the gas line. In addition, the plurality of gas lines are arranged in a housing equipped with an exhaust duct, and in the event of a leak from the fluid control device to the inside of the housing, the gas leakage to the outside of the housing is prevented during use. For this purpose, the inside of the housing is decompressed by a pump, and the air in the housing is discharged to a predetermined exhaust port via the exhaust duct. For this reason, an air flow is always generated in the housing.

  And the temperature of gas fluctuates because the flow of the air hits the heated gas line. As a result, the film forming process is affected, and the film forming accuracy is reduced.

  Then, an object of this invention is to provide the heat insulation cover which can suppress the temperature fluctuation of the gas which flows through the gas line by the flow of the air in a housing | casing, and a fluid control apparatus provided with the same.

  In order to solve the above-described object, a heat insulating cover according to an aspect of the present invention is a heat insulating cover for covering a gas line constituted by a plurality of fluid control devices connected to a joint, and is a short circuit of the gas line. A side having a pair of side wall portions that contact both side surfaces of the joint in the hand direction and face the plurality of fluid control devices in the short side direction, and an end wall portion provided at an end portion of the side wall portion A cover part, and an upper cover part provided on an upper part of the side cover part.

  Moreover, the said side cover part and the said upper cover part may respectively be comprised by the metal thin plate material and the heat insulating material provided so that it might overlap with the said thin plate material.

  Further, the side cover part and the upper cover part may be divided into two parts along a plane parallel to the side wall part passing through the center of the pair of side wall parts in the lateral direction. .

  The pair of side wall portions further includes a first clip having a pair of narrow pressure portions that narrows the pair of side wall portions from the outside and a connecting portion that connects the pair of narrow pressure portions. An opening is formed, and a slit into which the connecting portion is inserted is formed. The pair of narrow pressure portions includes a protruding portion that protrudes above the connecting portion, and the upper cover portion is disposed between the protruding portions. The connecting portion may support the upper cover portion from below.

  Moreover, you may provide the 2nd clip for integrating the said side cover part and the said upper cover part, and mounting | wearing with the said gas line.

  Further, a notch for accommodating a heater that contacts the joint is formed in one side wall portion of the side cover portion, and the second clip is configured to attach the heater to the gas line together with the side cover. May be.

  Moreover, the fluid control apparatus which is 1 aspect of this invention is equipped with said heat insulation cover which covers a part of gas line comprised by the some fluid control apparatus fixed to the coupling.

  ADVANTAGE OF THE INVENTION According to this invention, the heat insulation cover which can suppress the temperature fluctuation of the gas which flows through the gas line by the flow of the air in a housing | casing, and a fluid control apparatus provided with the same can be provided.

The top view of a fluid control apparatus provided with the heat insulation cover concerning this embodiment is shown. The perspective view of a gas line is shown. The perspective view of the gas line with which the heat insulation cover etc. were mounted | worn is shown. The perspective view which looked at the gas line with which the heat insulation cover etc. were mounted | worn from the angle different from FIG. 3 is shown. The perspective view of a heat insulation cover is shown. FIG. 6 is an exploded perspective view of the heat insulating cover when viewed from an angle different from that in FIG. 5. It is a figure which shows the state which attached the side cover part and the 1st clip to the gas line. It is a figure which shows the state which mounted | wore the gas line with the side cover part, the upper cover part, and the 1st clip.

  A heat insulating cover and a fluid control device according to an embodiment of the present invention will be described with reference to the drawings. The upper and lower sides in the following description are the upper and lower sides of FIGS. The inlet pipe 4 side is the upstream side of the gas flow, and the outlet pipe 5 side is the downstream side of the gas flow.

  FIG. 1 shows a plan view of a fluid control apparatus 1 according to the present embodiment. FIG. 2 shows a perspective view of the gas line 3.

  As shown in FIG. 1, the fluid control device 1 includes a base 2 and a plurality (four lines) of gas lines 3. Since the configuration of each gas line 3 is the same, only one gas line 3 among the plurality of gas lines 3 will be described below.

  As shown in FIGS. 1 and 2, the gas line 3 includes a plurality of joints 4 to 6 and a plurality of fluid control devices 7 to 13.

  The plurality of joints 4 to 6 are arranged in a line on the base 2, and are provided between an inlet pipe 4 that serves as a fluid inlet, an outlet pipe 5 that serves as a fluid outlet, and between the inlet pipe 4 and the outlet pipe 5. And a plurality of block-shaped joints 6 arranged on the surface. A gas flow path is formed in each of the joints 4 to 6. Moreover, the some coupling 6 is being fixed to the base | substrate 2 with the volt | bolt which is not shown in figure.

  The plurality of fluid control devices 7 to 13 include automatic valves (for example, fluid-driven automatic valves) 7 to 10, a manual regulator (reducing valve) 11, a pressure gauge 12, and a flow rate control device (for example, a mass flow controller). (MFC: Mass Flow Controller)) 13. As shown in FIG. 2, each of the fluid control devices 7 to 13 includes fixing portions 7A to 13A, and the fixing portions 7A to 13A have bolts 20 (only one bolt is provided with a reference number for simplification of the drawing). .) Are connected to the joint 6 respectively.

  FIG. 3 is a perspective view of the gas line 3 to which the heat insulating cover 30 and the like are attached. FIG. 4 is a perspective view of the gas line 3 to which the heat insulating cover 30 and the like are attached as viewed from an angle different from that in FIG.

  As shown in FIGS. 3 and 4, an aluminum block 14, a heater 15, a heater support plate 16, a heat insulating cover 30, an MFC heater 17, a heater fixture 18, and a thermostat 19 are attached to the gas line 3.

  The aluminum block 14 is provided so as to cover the inlet pipe 4.

  The heater 15 is a planar heater, and is provided so as to come into contact with the side surfaces of the fixing portions 7A and 11A of the automatic valve 7 and the regulator 11 and the side surface of the joint 6 to which the fixing portions 7A and 11A are fixed. The gas (for example, hydrogen fluoride) flowing in through the inlet pipe 4 is heated by the heat from the heater 15, and the liquefaction of the gas liquefied at room temperature is prevented.

  A heater support plate 16 is provided outside the heater 15. The heater support plate 16 supports the heater 15 and brings the heater 15 into close contact with the joint 6, the automatic valve 7, and the fixing portions 7 </ b> A and 11 </ b> A of the regulator 11.

  The heat insulating cover 30 is provided so as to cover both side surfaces of the joint 6, the automatic valves 7 to 9, the regulator 11, and a part of the pressure gauge 12. The detailed configuration of the heat insulating cover 30 will be described later.

  The MFC heaters 17 are planar heaters, and a pair of MFC heaters 17 are provided so as to contact both side surfaces of the lower part of the mass flow controller 13. The gas passing through the mass flow controller 13 is heated by the heat from the MFC heater 17, and the liquefaction of the gas is prevented.

  The heater fixture 18 is attached to the mass flow controller 13 so as to cover the entire outer periphery of the lower part of the mass flow controller 13 from the outside of the MFC heater 17. A pair of MFC heaters 17 are brought into close contact with the mass flow controller 13 by the heater fixture 18.

  The thermostat 19 is provided at the upstream end of the gas flow of the mass flow controller 13 and keeps the gas temperature below a predetermined temperature.

  Next, the detailed structure of the heat insulation cover 30 is demonstrated based on FIG.

  FIG. 5 shows a perspective view of the heat insulating cover 30, and FIG. 6 shows an exploded perspective view when the heat insulating cover 30 is viewed from an angle different from that in FIG. 5.

  As shown in FIG. 5, the heat insulating cover 30 includes a side cover portion 31, an upper cover portion 32, a first clip 33, and a second clip 34.

  As shown in FIG. 6, the side cover portion 31 includes a first side cover 35, a second side cover 36, a first side heat insulating member 37, and a second side heat insulating member 38.

  The first side cover 35 is formed by bending an aluminum alloy thin plate, and includes a first side wall portion 35A, a first upstream end wall portion 35B, a first downstream end wall portion 35C, And a support portion 35D. 35 A of 1st side wall parts comprise the substantially rectangular shape extended along the longitudinal direction of the gas line 3, a lower part contact | abuts one side surface of the coupling 6, and the upper part is automatic valves 7-9 in the transversal direction of the gas line 3. , The regulator 11 and the pressure gauge 12. Further, a notch 35e is formed on the upstream side of the gas flow in the lower portion of the first side wall portion 35A. The heater 15 and the heater support plate 16 are configured to fit in the notch 35e. Further, a slit 35f extending in the vertical direction is formed at a position corresponding to between the automatic valves 8 and 9 on the first side wall portion 35A.

  The first upstream end wall portion 35B has a substantially rectangular shape, and is provided at a substantially right angle to the first side wall portion 35A at the upstream end portion of the gas flow in the first side wall portion 35A. The tip of the first upstream end wall portion 35B is located near the center of the gas line 3 in the short direction. The short direction of the gas line 3 refers to a direction orthogonal to both the longitudinal direction and the vertical direction of the gas line 3.

  The first downstream end wall portion 35C has a substantially rectangular shape, and is provided at a substantially right angle to the first side wall portion 35A at the downstream end portion of the first side wall portion 35A.

  A plurality of first support portions 35D are provided along the longitudinal direction of the gas line 3 at the upper end portion of the first side wall portion 35A.

  The second side cover 36 is substantially plane-symmetric with respect to the first side cover 35 with a plane parallel to the longitudinal direction and the vertical direction of the gas line 3 and passing through the center of the gas line 3 in the short direction. I am doing. That is, the second side cover 36 is formed by bending a thin plate material of aluminum alloy, and the second side wall portion 36A corresponding to the first side wall portion 35A and the first upstream side end wall portion 35B. 2 has an upstream end wall portion 36B and a second support portion 36D corresponding to the first support portion 35D. The second side cover 36 does not have a portion corresponding to the first downstream end wall portion 35C.

  The second side wall portion 36 </ b> A has a lower portion in contact with the other side surface of the joint 6, and an upper portion facing the automatic valves 7 to 9, the regulator 11, and the pressure gauge 12 in the short direction of the gas line 3. A slit 36f extending in the vertical direction is formed at a position corresponding to between the automatic valves 8 and 9 on the second side wall portion 36A. Note that a cutout corresponding to the cutout 35e is not formed in the second side wall portion 36A.

  The tip of the second upstream end wall portion 36B is located near the center of the gas line 3 in the short direction, and is in close proximity to the tip of the first upstream end wall portion 35B.

  The first side heat insulating member 37 is made of a heat insulating material such as silicone sponge. The first side heat insulating member 37 is provided on the outer side of the first side cover 35 and has the first side cover 35 except that the first side heat insulating member 37 does not have portions corresponding to the first downstream end wall portion 35C and the first support portion 35D. It has almost the same shape. That is, the first side heat insulating member 37 has a third side wall portion 37A corresponding to the first side wall portion 35A and a third upstream end wall portion 37B corresponding to the first upstream end wall portion 35B. Therefore, the notch 37e is formed in the third side wall portion 37A, and the heater 15 and the heater support plate 16 are accommodated in the notch 37e. A slit 37f extending in the vertical direction is formed at a position corresponding to between the automatic valves 8 and 9 on the third side wall portion 37A.

  The first side cover 35 and the first side heat insulating member 37 are attached to the gas line 3 in a state where they are coupled to each other by an adhesive and overlapped in layers.

  The second side heat insulating member 38 is made of a heat insulating material such as silicone sponge. The second side heat insulating member 38 is provided on the outside of the second side cover 36 and has substantially the same shape as the second side cover 36 except that it does not have a portion corresponding to the second support portion 36D. That is, the second side heat insulating member 38 includes a fourth side wall 38A corresponding to the second side wall 36A and a fourth upstream end wall 38B corresponding to the second upstream end wall 36B. A slit 38f extending in the vertical direction is formed at a position corresponding to between the automatic valves 8 and 9 on the fourth side wall portion 38A.

  The second side cover 36 and the second side heat insulating member 38 are attached to the gas line 3 in a state where they are coupled to each other by an adhesive and overlapped in layers.

  The upper cover part 32 includes a first upper cover 39, a second upper cover 40, a first upper heat insulating member 41, and a second upper heat insulating member 42.

  The first upper cover 39 is made of an aluminum alloy thin plate and is disposed on the first support portion 35D. The first upper cover 39 has a substantially rectangular shape, and the width in the longitudinal direction and the short side direction is substantially equal to that of the first side heat insulating member 37. On the second side cover 36 side of the first upper cover 39, a plurality of substantially semicircular notches 39a (only one notch is provided with a reference number for simplification of the drawing) are formed. . Further, on the third side wall portion 37 </ b> A side of the first upper cover 39, a grip portion 39 </ b> B that extends upward is provided.

  The second upper cover 40 is made of an aluminum alloy thin plate and is disposed on the second support portion 36D. The second upper cover 40 is substantially plane-symmetric with respect to the first upper cover 39 with a plane parallel to the longitudinal direction and the vertical direction of the gas line 3 and passing through the center of the gas line 3 in the short direction. I am doing. Therefore, the second upper cover 40 is formed with a plurality of substantially semicircular cutouts 40a (only one cutout is provided with a reference number for simplification of the drawing), and a gripping portion 40B is provided. ing.

  The first upper heat insulating member 41 is made of a heat insulating material such as silicone sponge. The first upper heat insulating member 41 is provided on the upper side of the first upper cover 39 and has substantially the same shape as the first upper cover 39 except that it does not have a portion corresponding to the grip portion 39B. Therefore, a plurality of substantially semicircular notches 41a (only one notch is provided with a reference number for simplification of the drawing) are formed on the second side cover 36 side of the first upper heat insulating member 41. Has been.

  The first upper cover 39 and the first upper heat insulating member 41 are attached to the gas line 3 in a state where they are coupled to each other by an adhesive and overlapped in layers.

  The second upper heat insulating member 42 is made of a heat insulating material such as silicone sponge. The second upper heat insulating member 42 is provided on the upper side of the second upper cover 40 and has substantially the same shape as the second upper cover 40 except that it does not have a portion corresponding to the grip portion 40B. Accordingly, the second upper heat insulating member 42 is formed with a plurality of substantially semicircular cutouts 42a (only one cutout is given a reference number for simplification of the drawing).

  The second upper cover 40 and the second upper heat insulating member 42 are attached to the gas line 3 in a state where they are coupled to each other by an adhesive and overlapped in layers. When the upper cover portion 32 is attached to the gas line 3, as shown in FIG. 5, a plurality of substantially circular through holes 32a are formed by the substantially semicircular cutouts 39a to 42a. A part of the through hole 32a located on the most downstream side of the gas flow is opened.

  The first clip 33 is formed by bending a thin plate material, and includes a pair of narrow pressure portions 33A and a connecting portion 33B. The pair of narrow pressure portions 33A extends in the vertical direction and is parallel to the third side wall portion 37A and the fourth side wall portion 38A. The connecting portion 33B extends along the short direction of the gas line 3, and connects the pair of narrow pressure portions 33A. The connecting portion 33B is configured to be insertable into the slits 35f to 38f, and has a vertical width substantially equal to the vertical width of the slits 35f to 38f. Further, the upper end portion 33C of each narrow pressure portion 33A is configured to protrude upward from the connecting portion 33B. The upper end portion 33C corresponds to a protruding portion. The first clip 33 sandwiches the joint 6, the first side cover 35, the second side cover 36, the first side heat insulating member 37, and the second side heat insulating member 38 with a pair of narrow pressure portions 33 </ b> A. ing. Further, the first clip 33 supports the upper cover portion 32 from below by the connecting portion 33B, and prevents the upper cover portion 32 from being displaced by the upper end portion 33C.

  The second clip 34 is located upstream of the first clip 33 in the gas flow, is formed by bending a thin plate material, and includes a pair of narrow pressure portions 34A and a connecting portion 34B. The pair of narrow pressure portions 34A extend in the vertical direction and are parallel to the third side wall portion 37A and the fourth side wall portion 38A. The connecting portion 34B extends along the short direction of the gas line 3 and connects the pair of narrow pressure portions 34A. The second clip 34 includes a joint 6, a heater 15, a heater support plate 16, a first side cover 35, a second side cover 36, a first side heat insulating member 37, and a pair of narrow pressure portions 34A. The second side heat insulating member 38 is clamped. Moreover, the 2nd clip 34 presses the upper cover part 32 from upper side by the connection part 34B, and prevents the shift | offset | difference of the upper cover part 32 by a pair of narrow pressure part 34A. The side cover part 31 and the upper cover part 32 are integrated by the second clip 34. Further, the heater 15 and the heater support plate 16 are also attached to the gas line 3 by the second clip 34.

  As described above, the side cover part 31 and the upper cover part 32 pass through the center of the first side wall part 35A and the second side wall part 36A in the short direction of the gas line 3 and are parallel to the first side wall part 35A. Each is divided into two along the plane.

  Next, a method for attaching the heat insulating cover 30 to the gas line 3 will be described with reference to FIGS.

  FIG. 7 is a view showing a state where the side cover portion 31 and the first clip 33 are attached to the gas line 3. FIG. 8 is a view showing a state where the side cover portion 31, the upper cover portion 32, and the first clip 33 are attached to the gas line 3.

  First, the first side cover 35 and the first side heat insulating member 37 that are coupled to each other by an adhesive, and the second side cover 36 and the second side heat insulating member 38 that are coupled to each other by an adhesive are connected to the short side of the gas line 3. Place on both sides of the hand. The first clip 33 is lowered so that the connecting portion 33B of the first clip 33 is inserted into the slits 35f to 38f (FIG. 6), and the joint 6 and the first side cover 35 are connected by the pair of narrow pressure portions 33A. The second side cover 36, the first side heat insulating member 37, and the second side heat insulating member 38 are clamped. Thereby, the heat insulation cover 30 will be in the state shown in FIG.

  Next, the first upper cover 39 and the first upper heat insulating member 41, which have the holding portion 39B of the first upper cover 39 and are bonded to each other by an adhesive, are disposed on the first support portion 35D and the connecting portion 33B. To do. Similarly, the second upper cover 40 and the second upper heat insulating member 42, which have the holding portion 40B of the second upper cover 40 and are bonded to each other by an adhesive, are disposed on the second support portion 36D and the connecting portion 33B. To do. Thereby, as shown in FIG. 8, a plurality of through holes 32a are formed, and the automatic valves 7 to 9, the regulator 11, and the pressure gauge 12 pass through the respective through holes 32a.

  The second clip 34 is lowered so that the connecting portion 34B of the second clip 34 is located between the automatic valve 7 and the regulator 11, and the joint 6, the heater 15, and the heater are formed by the pair of narrow pressure portions 34A. The support plate 16, the first side cover 35, the second side cover 36, the first side heat insulating member 37, and the second side heat insulating member 38 are clamped. In this manner, the heat insulating cover 30 is attached to the gas line 3 as shown in FIG.

  According to the heat insulating cover 30 as described above, the side cover portion 31 and the upper cover portion 32 are configured to cover a part of the gas line 3. Temperature fluctuation of the gas flowing in the gas line 3 due to the air flow can be suppressed.

  The side cover portion 31 and the upper cover portion 32 include a first side cover 35, a second side cover 36, a first upper cover 39, and a second upper cover 40 made of a metal (aluminum alloy) thin plate material, and The first side heat insulating member 37, the second side heat insulating member 38, the first upper heat insulating member 41, and the second upper heat insulating member 42 made of a heat insulating material are provided on the outer side. With this configuration, the heat generated by the heater 15 is transmitted to the automatic valve 7 and the like by a metal having a relatively good thermal conductivity, and the outside heat insulating material can block the air from the outside and suppress heat dissipation. . As a result, temperature fluctuations of the gas flowing in the gas line 3 can be suppressed.

  Further, the side cover part 31 and the upper cover part 32 pass through the center of the first side wall part 35A and the second side wall part 36A in the short direction of the gas line 3 and are along a plane parallel to the first side wall part 35A. Each of them is divided into two parts. With this configuration, even if the gas line 3 is attached to the existing gas line 3 by modification or the like, it can be easily attached to the gas line 3 by access from above.

  Since the side cover portion 31 and the upper cover portion 32 are integrated by the second clip 34 and attached to the gas line 3, the heat insulating cover 30 can be easily attached to the gas line 3 without using screws or the like. Can be installed.

  Since the heater 15 and the heater support plate 16 are also attached to the gas line 3 by the second clip 34, it is not necessary to separately provide components for mounting the heater 15 and the like, so that the number of components can be reduced.

  In addition, this invention is not limited to embodiment 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 embodiment, the heat insulating cover 30 is configured to cover a part of the fluid control devices 7 to 9, 11, and 12, but at least the flow paths of the fluid control devices 7 to 9, 11, and 12 are formed. What is necessary is just to comprise so that the performed part may be covered, and you may comprise so that the whole fluid control apparatus 7-9, 11, 12 may be covered.

  The first side cover 35, the second side cover 36, the first upper cover 39, and the second upper cover 40 are made of an aluminum alloy. However, other materials can be used as long as they have good thermal conductivity. May be. Moreover, although the 1st side heat insulation member 37, the 2nd side heat insulation member 38, the 1st upper heat insulation member 41, and the 2nd upper heat insulation member 42 were comprised with silicone sponge, if it is a material with good heat insulation, other It may be a material. Moreover, although the side cover part 31 was divided into 2 along the longitudinal direction, it may be divided into 2 along the transversal direction, and may be comprised integrally. The side cover part 31 and the upper cover part 32 are configured to provide a heat insulating material so as to be layered on the outer side of the metal thin plate material, but the metal thin plate material is provided so as to be layered on the outer side of the heat insulating material. The structure provided may be sufficient.

  The downstream end of the gas flow of the side cover portion 31 is open due to the presence of the thermostat 19, but when there is no thermostat 19, it may be configured to close in the same manner as the upstream side.

  Although the heat insulating cover 30 is configured to be attached to the gas line 3 by the first clip 33 and the second clip 34, the heat insulating cover 30 may be configured to be attached to the gas line 3 using only the second clip 34. .

  In the above-described embodiment, the fluid control device 1 includes an automatic valve, a pressure gauge, a regulator, and a mass flow controller as fluid control devices, but may include a manual valve, a filter, and the like in addition to these.

1: Fluid control device 3: Gas line 6: Joints 7 to 13: Fluid control device 15: Heater 30: Heat insulation cover 31: Side cover part 32: Upper cover part
33: First clip 33A: Narrow pressure part
33B: Connection part
33C: upper end 34: second clip 35: first side cover 35A: first side wall 35B: first upstream end wall 36: second side cover 36A: second side wall 36B: second upstream end wall Part 37: first side heat insulating member 37A: third side wall part 37B: third upstream end wall part 38: second side heat insulating member 38A: fourth side wall part 38B: fourth upstream side end wall part 39: first upper part Cover 40: second upper cover 41: first upper heat insulating member 42: second upper heat insulating member

Claims (7)

A heat insulating cover for covering a gas line constituted by a plurality of fluid control devices connected to a joint,
A pair of side wall portions for contacting both side surfaces of the joint in the short direction of the gas line and facing the plurality of fluid control devices in the short direction, and end wall portions provided at end portions of the side wall portions And a side cover portion having
A heat insulating cover comprising: an upper cover portion provided on an upper portion of the side cover portion.   The said side cover part and the said upper cover part are the heat insulation covers of Claim 1 comprised by the metal thin plate material and the heat insulating material provided so that it might overlap with the said thin plate material, respectively.   The said side cover part and the said upper cover part are each comprised in 2 division along the surface parallel to the said side wall part through the center of the said pair of side wall part in the said transversal direction. The heat insulation cover of Claim 1 or Claim 2. A first clip having a pair of narrow pressure portions for narrowing the pair of side wall portions from the outside and a connecting portion for connecting the pair of narrow pressure portions;
The pair of side wall portions are formed with slits that open at their upper ends and into which the connecting portion is inserted,
The pair of narrow pressure portions includes a protruding portion protruding upward from the connecting portion,
The heat insulating cover according to claim 3, wherein the upper cover portion is disposed between the protruding portions, and the connecting portion supports the upper cover portion from below.   The heat insulation cover as described in any one of Claims 1-4 provided with the 2nd clip for integrating the said side cover part and the said upper cover part, and mounting | wearing with the said gas line. On one side wall portion of the side cover portion, a notch for receiving a heater that contacts the joint is formed,
The said 2nd clip is a heat insulation cover of Claim 5 comprised so that the said heater may be mounted | worn with the said side line with the said side cover.   A fluid control apparatus provided with the heat insulation cover as described in any one of Claims 1-6 which covers a part of gas line comprised by the some fluid control apparatus fixed to the coupling.

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