JP2015059440A - Evacuation method and evacuation facility - Google Patents

Abstract

PROBLEM TO BE SOLVED: To shorten evacuation time according to the volume of a processing chamber without increasing the facility size.SOLUTION: In evacuation in which a processing chamber (chamber 3) and a vacuum pump 2 are connected by a pipeline 5, in the case where the volume of the pipeline 5 becomes larger than the volume of the processing chamber 3 when the diameter of the pipeline 5 is made to be the same as the diameter of a suction port 11 of the vacuum pump 2, evacuation of the processing chamber 3 is performed by using the pipeline 5 whose diameter is smaller than the diameter of the suction port 11. It is preferable that the diameter of the pipeline 5 which is smaller than the diameter of the suction port 11 is the diameter at the time when exhaust speed calculated from synthesis conductance of the pipeline 5 and a valve 4 and evacuation capacity of the vacuum pump 2 becomes the fastest.

Description

  The present invention relates to a vacuum evacuation method and vacuum evacuation equipment for evacuating a processing chamber such as a carburizing furnace, and particularly to vacuum evacuation for shortening the vacuum evacuation time in equipment having a processing chamber with a small volume. The present invention relates to a method and an evacuation facility.

  Carburizing treatment of a workpiece such as steel is performed in a carburizing furnace as disclosed in Patent Document 1, for example. The carburizing furnace has a plurality of heat treatment chambers consisting of a preheating chamber, a carburizing chamber, a cooling chamber, a quenching chamber, etc., and a preheat treatment, a carburizing treatment, a cooling treatment, and a quenching treatment while sequentially moving the workpieces to each heat treatment chamber. Etc. are continuously performed. Each of the heat treatment chambers is evacuated and then supplied with a predetermined gas to heat-treat the object to be processed at a predetermined temperature.

  In such a carburizing furnace, it is required to shorten the cycle time in order to improve the operation efficiency. In particular, when the object to be processed is transported between a plurality of heat treatment chambers, it is necessary to shorten the evacuation time of each heat treatment chamber in order to shorten the cycle time.

  Conventionally, the vacuum pump for evacuating the carburizing furnace has been determined according to the volume of the heat treatment chamber. Therefore, conventionally, in order to improve the evacuation capacity, the number of pumps is increased or the pumps are increased in size, resulting in an increase in equipment cost.

  Further, in the carburizing furnace, when the object to be processed is carried into or out of the carburizing furnace, a conveying unit that conveys the object to be processed is docked in the carburizing furnace, and a connection portion between the conveying unit and the inlet or outlet of the carburizing furnace is provided. After being evacuated, the carburizing furnace door opens. This connecting portion has a volume of about several liters to 10 liters, which is extremely small compared to the heat treatment chamber.

JP 2011-74435 A

  Conventionally, pipes connected to the vacuum pump for evacuating each heat treatment chamber as described above have the same diameter as the suction port diameter of the vacuum pump. This is for efficiently and maximizing the capacity of the vacuum pump, but when evacuating with a large vacuum pump, the efficiency may decrease in the case of a space with a small volume such as a connecting part. . That is, when the volume of the pipe is large with respect to the chamber having a small volume, the ratio of evacuating the inside of the pipe becomes large, and a wasteful exhaust time is required. Therefore, in this case, even if the vacuum pump is enlarged, waste is increased.

  The present invention has been made to solve the above-described problem, and an object thereof is to shorten the evacuation time according to the volume of the processing chamber without increasing the equipment size.

  In order to solve the above problem, the present invention provides a vacuum evacuation method in which a processing chamber and a vacuum pump are connected by a pipe, and when the pipe has the same diameter as the inlet of the vacuum pump, the volume of the pipe is A vacuum evacuation method is provided in which the processing chamber is evacuated using a pipe having a diameter smaller than the diameter of the intake port when the volume of the processing chamber becomes larger.

  In the vacuum exhaust method, it is preferable that the diameter of the pipe having a diameter smaller than the diameter of the intake port is 25% to 75% of the diameter of the intake port. Further, it is preferable that the diameter of the pipe having a diameter smaller than the diameter of the intake port is a diameter at which the exhaust speed calculated from the combined conductance of the pipe and the valve and the vacuum exhaust capacity of the vacuum pump becomes the fastest.

  Further, the present invention is an evacuation facility in which a processing chamber and a vacuum pump are connected by piping, and when the piping has the same diameter as the diameter of the suction port of the vacuum pump, the volume of the piping is the volume of the processing chamber. In this case, the diameter of the pipe connected to the processing chamber is smaller than the diameter of the intake port, and the exhaust speed calculated from the combined conductance of the pipe and the valve and the vacuum exhaust capacity of the vacuum pump is the fastest. Provided is an evacuation facility characterized by having a diameter when

  Further, the present invention is an evacuation facility in which a plurality of processing chambers having different volumes and one vacuum pump are connected by piping, and the diameter of the piping connected to each processing chamber is a combination of the piping and the valve. There is provided an evacuation facility having a diameter at which the evacuation speed calculated from the conductance and the evacuation capacity of the vacuum pump is the fastest.

  The vacuum evacuation facility may be a facility for evacuating the heat treatment chamber of the carburizing furnace.

  According to the present invention, since the evacuation time can be shortened according to the volume of the processing chamber, the cycle time in the heat treatment furnace or the like is shortened, the efficiency is increased, and the cost can be reduced.

It is a block diagram which shows the outline | summary of the vacuum processing equipment concerning this invention. It is a block diagram of the vacuum processing equipment which shows an example of embodiment of this invention. It is a block diagram of the vacuum processing equipment which shows the example of different embodiment of this invention. It is a graph which shows the exhaust time by the piping diameter of the chamber b. It is a graph which shows the exhaust time by the piping diameter of the chamber c. It is explanatory drawing which compared the exhaust time by the piping diameter of three types of chambers.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows an example of an embodiment of an evacuation equipment 1 according to the present invention. A single vacuum pump 2 and a chamber 3 are connected via a pipe 5 provided with a valve 4. When the volume of the chamber 3 is sufficiently larger than the volume (inner diameter × length) of the pipe 5, the pipe 5 has the same diameter as the exhaust port 11 of the vacuum pump 2. Is equal to or smaller than the volume of the pipe 5, the diameter of the pipe 5 is made smaller than the exhaust port 11 of the vacuum pump 2. At this time, the diameter of the pipe 5 is preferably in the range of 25% to 75% of the diameter of the exhaust port 11 of the vacuum pump 2. If it is less than 25%, the exhaust conductance becomes too large and the exhaust time becomes long, and if it exceeds 75%, the effect of reducing the volume of the pipe 5 is low.

  The present inventors can shorten the evacuation time by reducing the volume of the pipe 5 even if the exhaust conductance is increased by reducing the diameter of the pipe 5 connecting the vacuum pump 2 and the chamber 3. I found out. Hereinafter, an example of a method for calculating the evacuation speed in consideration of conductance will be described.

First, the conductance C ₂₄ (L / min) of the pipe 5 is obtained by the following formula (1) described in “Back Vacuum Handbook Revised Edition 3 P.41” edited by ULVAC, Inc.
C ₂₄ = 1349 * (d ⁴ / L) × (P ₁ + P ₂ ) / 2 (1)
d: Piping diameter L: Piping length P ₁ : Upstream pressure P ₂ : Downstream pressure

Next, using the result of the equation (1), the combined conductance C (L / min) of the pipe 5 and the valve 4 is calculated by ULVAC, Inc. “Vacuum Handbook Revised Edition 3 P.36, FIG. 7.5-a”. It calculates | requires by the following formula | equation (2) described in.
1 / C = 1 / C ₁ + 1 / C ₂₄ (2)
C ₁ : Conductance of the valve (obtained from the valve manufacturer)

Using the above calculation results, the evacuation speed S ₁ (m ³ / sec) of the entire vacuum piping system is expressed by the following formula (3) described in ULVAC, Inc. “Vacuum Handbook Revised Edition 3 P.38”: Is required.
1 / S ₁ = 1 / C + 1 / S ₀ (3)
S ₀ : Vacuum pumping capacity of the vacuum pump (obtained from the manufacturer)

Evacuation speed S ₁ obtained by the equation (3) is to be preferred target value in operation of equipment to determine the diameter d of the pipe 5. In order to accurately calculate the actual exhaust time, a coefficient is obtained from the ratio between the conductance actually measured with a pipe having an arbitrary diameter and the calculated value of the combined conductance C using the above equation (2). A value multiplied by a coefficient may be used as conductance.

  If the pipe 5 has the same diameter as the exhaust port 11 of the vacuum pump 2, the volume of the pipe 5 becomes larger than the volume of the chamber 3, or the volume of the pipe 5 is very large relative to the volume of the chamber 3, It is effective to use the pipe 5 having a diameter d that is smaller than the exhaust port 11 of the pump 2 and that is obtained by the above calculation and has the shortest exhaust time.

  FIG. 2 shows a different embodiment of the present invention. For example, an evacuation facility 1 for evacuating a heat treatment chamber of a carburizing furnace has a single vacuum pump 2 and a plurality of chambers 3a, 3b, 3c, Each is connected via a pipe 5 provided with a valve 4. The chambers 3 have different volumes, for example, the chamber 3a is a heat treatment chamber, the chamber 3b is a transfer unit for transferring an object to be processed, and the chamber 3c is a connecting portion between the heat treatment chamber and the transfer unit. In this evacuation facility 1, if the pipe having the same diameter as the exhaust port 11 of the vacuum pump 2 is used, the volume of the pipe is larger than the volume of the chamber 3 c, so the diameter is smaller than that of the exhaust port 11 and the exhaust time is the shortest. A pipe 5 having a diameter is connected to each chamber 3a, 3b, 3c.

  FIG. 3 shows yet another embodiment of the present invention. A plurality of chambers 3a, 3b, 3c are provided in the same manner as the evacuation equipment 1 shown in FIG. 2, and the diameter of the pipe 5 connected to the plurality of chambers 3a, 3b, 3c is the volume of the chambers 3a, 3b, 3c. Accordingly, the exhaust time is determined to be optimum. In the case of FIG. 3, the pipe 5c connected to the chamber 3c has a smaller diameter than the pipes 5a and 5b connected to the other chambers 3a and 3b.

  In the case of having a plurality of chambers 3, conventionally, the configuration of the vacuum exhaust system is determined by the volume of the maximum volume chamber 3 a and the exhaust amount of the vacuum pump 2, and the diameter of the pipe 5 is the same as the diameter of the intake port 11 of the vacuum pump 2. It was the same diameter. In the present invention, the optimum pipe diameter d that can shorten the exhaust time is calculated by determining the pipe diameter in consideration of not only the volume of the chamber 3 and the exhaust amount of the vacuum pump 2 but also the volume of the pipe 5 and the conductance. It became possible. Accordingly, it is possible to complete the vacuum exhaust in a shorter time without shortening the cycle time without adding the vacuum pump 2 or changing to a large pump.

  Hereinafter, an example of a method for determining the pipe diameter will be described more specifically.

A chamber a having a volume of 0.2255 m ³ as an example of the heat treatment chamber of the carburizing furnace, a chamber b having a volume of 0.059 m ³ as an example of the transfer unit for the object to be processed, and a volume as an example of a connecting portion between the transfer unit and the heat treatment chamber Evacuation time depending on the pipe diameter was examined for chambers of three different volumes, chamber c of 0.0044 m ³ .

  The vacuum pump was a dry vacuum pump LR180 (inlet diameter 80 mm) manufactured by ULVAC, and the piping length from the vacuum pump to each chamber was 10.4 m.

The vacuum pump is sized to evacuate the heat treatment chamber of the chamber a. When an 80A pipe having the same diameter as that of the intake port is used, the volume of the pipe is 0.050 m ³ , greatly exceeding the volume of the chamber c. . Therefore, when the chamber c is evacuated with the 80A pipe, the amount of exhaust in the pipe is much larger than in the chamber, resulting in poor efficiency. Therefore, first, the exhaust time was measured for the three types of chambers a, b, and c with the pipe of 20A. The exhaust time was the time required to reach 500 Pa from atmospheric pressure.

  Next, the measured value of conductance at the time of measurement using the 20A pipe was compared with the calculated value of conductance according to the above-described calculation formula, and the coefficient for the product of the calculated value to be the measured value was obtained. The calculated value of conductance was corrected with this coefficient, and the exhaust times when the pipes were 25A, 40A, 50A, 65A, and 80A for the chambers b and c were calculated by the above-described equations (1) to (3).

  FIG. 4 and FIG. 5 show the measured values of the exhaust time for the pipes of 20A and the calculated values of the exhaust times for the pipes of 25A, 40A, 50A, 65A, and 80A for the chambers b and c, respectively. is there. As shown in FIG. 4, the exhaust time was about 10 seconds or less in the case of 40A to 65A in the chamber b, and the exhaust time was 3 seconds or less in the case of 40A in the chamber c as shown in FIG. From these, it can be seen that in the case of the 40A pipe, the exhaust time is shortened for both the chambers b and c.

  Therefore, the chambers a, b, and c were evacuated by connecting a 40A pipe. FIG. 6 shows an exhaust time required for evacuation in each chamber when a vacuum pump is connected to three types of chambers a, b, and c via three types of pipes having a pipe diameter of 20A, 40A, and 80A. Is shown. The pipe diameters 20A and 40A are actually measured values, and 80A are calculated values.

As shown in FIG. 6, the chamber a having a large volume has a shorter exhaust time when the pipe diameter is larger. However, in the case of the chamber c having a very small volume, the exhaust time by the 40A pipe is the shortest, and the 80A pipe. Due to the longest exhaust time. The volume of the 40A pipe is 0.014 m ³ , which is larger than the volume of the chamber c. However, in the 20A pipe having a volume smaller than the volume of the chamber c, the conductance is too small and the exhaust time is long. Therefore, it was found that when evacuating a small volume chamber, it is most efficient to set the pipe diameter so that the pipe volume with respect to the chamber does not become too large and the conductance does not become too small. Furthermore, as shown in FIG. 6, even for the chamber a having the largest volume, vacuum exhaust can be performed with a 40 A pipe in approximately the same exhaust time as in the case of 80 A.

  From the above, when the chambers a, b, and c are evacuated, all the pipes may be set to 40A. For example, only the pipe connected to the chamber a having a large volume is set to 80A, and the pipes connected to the chambers b and c are set to 40A. It is also good.

  As mentioned above, although preferred embodiment of this invention was described, this invention is not limited to this example. It is obvious for those skilled in the art that various changes or modifications can be conceived within the scope of the technical idea described in the claims. It is understood that it belongs to.

  The present invention can be applied to a small-scale vacuum processing chamber, and is particularly suitable for a vacuum processing chamber in which the amount of work per lot is small and evacuation and atmospheric release are frequently repeated.

DESCRIPTION OF SYMBOLS 1 Vacuum exhaust equipment 2 Vacuum pump 3, 3a, 3b, 3c Chamber 4 Valve 5, 5a, 5b, 5c Piping

Claims (6)

In a vacuum exhaust method in which a processing chamber and a vacuum pump are connected by piping,
If the pipe has the same diameter as the suction port of the vacuum pump, and if the volume of the pipe is equal to or larger than the volume of the processing chamber, the processing chamber is evacuated using a pipe having a diameter smaller than the diameter of the suction port. A vacuum evacuation method characterized in that:   2. The vacuum exhaust method according to claim 1, wherein a diameter of a pipe having a diameter smaller than a diameter of the intake port is 25% to 75% of a diameter of the intake port.   The diameter of the pipe having a diameter smaller than the diameter of the intake port is a diameter at which the exhaust speed calculated from the combined conductance of the pipe and the valve and the vacuum exhaust capacity of the vacuum pump is the fastest, The vacuum exhaust method as described in any one of Claim 1 or 2. A vacuum exhaust system in which a processing chamber and a vacuum pump are connected by piping,
If the pipe has the same diameter as the suction port of the vacuum pump, and the volume of the pipe is equal to or greater than the volume of the processing chamber, the diameter of the pipe connected to the processing chamber is smaller than the diameter of the suction port. A vacuum exhaust system having a diameter at which the exhaust speed calculated from the combined conductance of the pipe and the valve and the vacuum exhaust capacity of the vacuum pump is the fastest. A vacuum exhaust system in which a plurality of processing chambers having different volumes and one vacuum pump are connected by piping,
The diameter of the pipe connected to each processing chamber is the diameter at which the exhaust speed calculated from the combined conductance of the pipe and the valve and the vacuum exhaust capacity of the vacuum pump is the fastest. Facility.   6. The vacuum exhaust equipment according to claim 4, wherein the vacuum exhaust equipment is equipment for vacuum exhausting a heat treatment chamber of a carburizing furnace.

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