JPH037028B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a large-capacity cryopump used as a pump for evacuation.

[Technical background of the invention and its problems]

The outline of the structure of a cryopump used as a vacuum evacuation pump is shown in FIG. In Figure 1, 1 is the cryopanel.
It is cooled with liquid helium at a temperature of 4.2K or below. The cryopanel 1 is surrounded by a shield plate 2 cooled with liquid nitrogen at approximately 80K, except for the exhaust opening, and the opening is covered with a corrugated lattice-shaped sheapron batsful or louver blind 3 (lined in the figure). Although it is shown in , it actually has a thin plate, and the same is true for other figures). The evacuation action of the cryopump is to direct residual gas molecules in the vacuum container 4 through an opening in the sieve valve or louver blind 3,
This is caused by condensation and adsorption on the surface of the cryopanel 1 that has been cooled to a temperature of 4.2K or lower.

The cryopump is characterized by the number per unit opening area/sec・in a vacuum of about 10 ^-5 Torr.
cm ² and has a large pumping speed. Important factors that determine this pumping speed include the shape of the opening, ie, the opening angle of the apron buttle or louver blind, and the shape of the mounting pitch.

Recently, a unit type cryopump using a louver blind as shown in FIG. 2 has been devised. The louver blind is characterized in that the gas molecule passage probability η is approximately twice as large as the passage probability of the Siepron Buffful. Third
The figure shows the detailed shape of a part of it.

As shown in FIG. 3, the cryopanel 1 is arranged parallel to the gas molecule entry direction 5, and θ ₁
Louvers 3 with an opening angle of are provided at a constant pitch. When the distance between each unit is a and the width of the unit is b, the passage probability η of gas molecules per unit is determined by the following equation.

η=η _a ·a/(a+b) Here, η _a represents the probability of passage between units.

The passage probability η _a between units is controlled by the passage probability η _L of the louver 3, and the relationship between η _a and η _L is η _a ∝η _L. However, in the cryopump shown in FIG. 3, although both sides of the cryopanel 1 are used as condensing surfaces, the pumping speed is restricted because the passage probability η _L of the louver blind 3 is small. The reason for this is that because the louvers are arranged in parallel, there are stagnant gas molecules that keep reflecting between the louvers, and the probability that they will reach the cryopanel or fly out is 1/2, respectively.
In order to increase the pumping speed, it is necessary to eliminate these causes.

[Purpose of the invention]

An object of the present invention is to provide a high pumping speed cryopump having a louver blind with a high gas molecule passage rate.

[Summary of the invention]

In the present invention, in a cryopump having a cryopanel cooled with liquid helium and a louver blind cooled with liquid nitrogen,
The cryopanel is installed perpendicular to the exhaust opening, and the louver blinds are arranged on both sides with opening angles that gradually increase from the opening angle at the front, and heat radiation from the room temperature area is directly directed to the cryopanel surface. By having louver blinds whose arrangement pitch is greatly varied within the limits that do not interfere with each other, a cryopump with a high pumping speed having a louver blind with a high gas molecule passage rate can be obtained.

[Embodiments of the invention]

An embodiment of the present invention will be described below with reference to FIG. In FIG. 4, 1 is a cryopanel and 3 is a louver blind. The louver blind 3 is blackened so that its emissivity is close to 1. The opposite side is surrounded by a nitrogen shield 2 whose inner surface is blackened. The louver blind 3 is set based on the opening angle θ ₁ of the frontmost louver as shown in Fig. 4.
The opening angle of the last louver is θ _2. However, θ ₁
<θ ₂ .

Furthermore, the mounting pitch of the louver blind 3 is gradually changed so that the path 6 of light or heat radiation from the room temperature side does not directly reach the cryopanel 1 under the worst conditions. Deploy.

In the louver blinds 3 configured in this way, since the louver blinds 3 are non-parallel to each other, there are theoretically no particles that continue to be reflected between the louver blinds 3.
Further, since the path between the louver blinds 3 is open to the cryopanel 1 side, the direction in which the light is reflected and travels is toward the cryopanel 1 side due to the reflection angle.

Furthermore, when the louver blind 3 is viewed perpendicularly to one surface of the cryopanel, the structure allows a large area from which the cryopanel can be viewed directly. These act to increase the passage probability η _L of the louver blind 3. Thermal radiation from the room temperature section does not reach the cryopanel 1. Furthermore, since the pumping speed of the cryopump is determined by the passage probability η _a between units, the passage probability η of the entire unit increases, leading to an increase in the pumping speed.

〔Effect of the invention〕

As explained above, the present invention has the following effects.

By sequentially changing the opening angle of each louver blind, the facing surfaces between the louver blinds become non-parallel surfaces, which reduces the number of gas molecules staying between the louver blinds and also allows the facing surfaces to open toward the cryopanel side. Its shape makes it easier to reach the cryopanel. Thermal radiation from the room temperature section does not reach the cryopanel. These things increase the probability η of gas molecules passing through the louver blind, and can dramatically increase the actual pumping speed.

Furthermore, when producing cryopumps having the same pumping speed, the structure of the present invention has the advantage that the apparatus can be made more compact.

[Brief explanation of drawings]

FIG. 1 is a schematic cross-sectional view showing the structure of a cryopump, FIG. 2 is a cross-sectional view showing the main parts of a conventional cryopump, and FIG. 3 is a cross-sectional view showing two units in FIG. 2 enlarged. FIG. 4 is a sectional view showing essential parts of an embodiment of the cryopump of the present invention. 1... Cryopanel, 2... Nitrogen shield,
3...Louvred blind or siebron buttful, 4...Vacuum container, 5...Arrow showing the progress of gas molecules, 6...Arrow showing the course of light or thermal radiation.

Claims (1)

[Claims] 1. In a cryopump that has a cryopanel cooled with liquid helium and a louver blind cooled with liquid nitrogen, the cryopanel is installed perpendicularly to the exhaust opening, and the cryopanel is installed on both sides with reference to the opening angle of the frontmost part. A cryopump characterized in that the louver blinds are arranged with opening angles that are gradually increased, and the pitch of the louver blinds is gradually changed to the extent that heat radiation from the normal temperature part does not directly hit the cryopanel surface.