KR920002652B1 - Diaphragm and sealed shell coupling incorporating same - Google Patents

Abstract

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Description

Diaphragm and Sealed Shell Joints

1 is a cross-sectional view of a brake booster comprising a housing for supporting the improved diaphragm of the present invention and used to form such a housing to obtain a single-shell engagement portion incorporating the improved diaphragm therein.

2A is an enlarged cross-sectional view of the outer periphery and shell projection of an improved diaphragm forming the basic components of the present invention.

2b is an enlarged cross sectional view showing the basic components of a sealed shell housing of a brake booster formed by a sealed shell engaging portion according to the prior art;

* Explanation of symbols for main parts of the drawings

1 housing 2 first shell

2a: open end 3: second shell

4: diaphragm 4a: thick outer periphery

4b: annular groove 4c: outer edge

5: forward pressure chamber 6: rear pressure chamber

7: radial stepped portion 8: enlarged diameter portion

9: flange portion 10: brake booster

11: annular projection

FIELD OF THE INVENTION The present invention generally relates to diaphragms for partitioning the interior of a container into two sealed chambers, in particular an improved diaphragm suitable for partitioning a pressure chamber in a housing, such as a brake booster, and a seal incorporating such a diaphragm. It is about a shell joint.

A booster device such as a brake booster controls the opening and closing of the valve mechanism via an operating rod that is linked to the brake pedal, thereby introducing atmospheric pressure into the transformer chamber during brake operation, thereby reducing the pressure difference between the transformer chamber and the constant pressure chamber (or negative pressure chamber). The boost function is applied to the power piston. When the brake is released, the communication between the transformer chamber and the atmosphere is interrupted and the transformer chamber is communicated with the positive pressure chamber (or the negative pressure chamber) so that the power piston is returned to the non-operation position by the feedback spring. As described above, the power piston operated by the pressure difference between the transformer chamber and the constant pressure chamber (or negative pressure chamber) is attached to the housing by a diaphragm. Generally, such a housing consists of a cup-shaped first shell and a dish-shaped second shell which is inserted into the open end of the first shell and mechanically coupled to the first shell. By inserting, the transformer chamber on one side of the diaphragm defines a positive pressure chamber (or negative pressure chamber) on the other side. As can be seen clearly, in order to achieve the proper function of the booster, a diaphragm-tightening connection between the first and second shells is required and a diaphragm portion sandwiched between the first and second shells is required. It is formed considerably thicker than the other parts to obtain a satisfactory fastening effect by the coupling between the two shells. In making such a joint between the two shells, attaching the diaphragm to the housing of the booster is positioned with the inner surface of the second shell facing upwards, and a diaphragm in the form of a disc placed on the upper surface thereof. Keeping the thick outer periphery of the fram installed on the outer periphery of the second shell, with the open end of the first shell facing downward, its axis aligned with the axis of the second shell, and then the first shell attached to the second shell. Pressing downwards to achieve engagement and insert the thick outer periphery of the diaphragm between the first and second shells.

However, since the diaphragm portion fastened between the first and second shells is usually formed thick, it is particularly important to maintain the attachment state or position of the diaphragm in the second shell when the first shell is pressed against the second shell. Stability of the diaphragm is displaced with respect to the second shell when the first shell is brought into contact with the diaphragm during the installation and fastening of the first shell onto the second shell. It may be detached from the outer circumference of the shell. When the coupling between the first and second shells is completed with the diaphragm displaced in this manner, sufficient airtightness cannot be obtained between the first and second shells. Therefore, the assembling work of the diaphragm sandwiched between the first and second shells and their circumference has to be done carefully, and despite such care, it has been practically difficult to ensure sufficient sealing between the first and second shells.

Accordingly, the present invention has been made to solve the above-described problems, and the diaphragm is assembled when the first shell is assembled to the second shell to form a housing such as a buster with the outer circumference of the diaphragm being sandwiched between the two shells. It is aimed at ensuring the stability of the diaphragm in the second shell sufficient to prevent displacement against two cells or peel off from the second shell.

The present invention relates to an improved diaphragm and a sealed shell joint in which the diaphragm is incorporated. The present invention is in part related to a diaphragm with an outer circumferential edge sandwiched between the first and second shells for forming a fluid sealing chamber on each side with respect to a housing such as a booter, wherein the first shell is The cup is shaped like a cup with an enlarged diameter portion radially end to the end, and the second shell has a radially extended end diameter of the first shell adjacent to the outer circumferential edge such that its outer diameter generally coincides with the inner diameter of the first shell. It is in the form of a disc which ends confined to a folded annular projection projecting radially inwardly in the minor outer corner. The diaphragm includes a thick outer periphery and an annular groove having a size and a position corresponding to the annular projection and formed in the surface of the outer periphery, so that the thick outer periphery of the diaphragm has an annular groove formed in the outer peripheral surface of the disc diaphragm. Take the annular projection of the shell and insert the thick outer circumference of the diaphragm between the radially enlarged diameter of the cup-shaped first shell with the open end and the outer circumference of the second shell to prevent displacement of the diaphragm while the shells are engaged. To be secured to the second shell.

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

Referring to FIG. 1, a brake booster 10 is shown in which part of the breaker is cut away to clearly show the engagement between the first and second shells forming the housing 1 of the brake booster. In that respect, the first shell 2 is arranged at the front side of the brake booster and the second shell 3 is arranged at the rear side thereof. The interior of the housing 1 is generally partitioned into a front pressure chamber 5 and a rear pressure chamber 6 by diaphragms 4 in the form of circular or discs, which diaphragms 4 are first and second. It has a relatively thick outer periphery 4a fitted to the engaging portion between the shells 2 and 3. Such a brake booster controls the opening and closing of a valve mechanism (not shown) of a conventional type, thereby generating a pressure difference between the front pressure chamber 5, which is a positive pressure chamber, and the rear pressure chamber 6, which is a transformer pressure chamber, to perform a boost function.

The first shell 2 has a cup shape, and an enlarged diameter portion 8 is provided at the opening end 2a via the radiation step portion 7. The second shell 3 is in the shape of a disc or a shallow dish and includes an annular projection 11 that is bent against its outer circumference and generally coincides with the inner diameter of the enlarged diameter portion 8 of the first shell 2. A flange portion 9 having a portion is formed.

As can be seen, the flange portion 9 of the disc-shaped second shell 3 is first bent at a right angle to the main portion of the shell, then folded back and finally bent at 90 ° radially outward, The diameter is enlarged to correspond to that of the enlarged diameter portion 8 of the first shell 2. This folded portion forms the annular protrusion 11.

In accordance with an important concept of the present invention and in relation to the formation of the annular projection 11 of the second shell 3, the thick outer peripheral portion 4a formed at the outer peripheral edge of the diaphragm 4 is provided with a second shell 3. An annular groove 4b of a size and shape capable of tightly receiving the annular projection 11 to be engaged is provided along the radial surface of the diaphragm.

Therefore, when the diaphragm 4 is installed on the second shell 3, the annular projection 11 of the second shell 3 is fitted into the annular groove 4b of the diaphragm outer peripheral portion 4a. The diaphragm 4 can be stably fixed to an appropriate position of the second shell 3 before the coupling between the shells 2 and 3 is finished. Therefore, even if the first shell 2 is displaced axially toward the second 3, the diaphragm 4 does not cause displacement with respect to the shells 2, 3, and the outer periphery of the first shell 2 does not cause displacement. The diaphragm 4 with respect to the second 3 can be positioned exactly coaxially with respect to the first shell 2 in a state consistent with the radially enlarged diameter portion 8 of one shell 2. It is possible to increase the centering effect of the center of the axis precisely, to allow the first and second shells and the diaphragm 4 to be set coaxially to properly complete the coupling between the shells, and the two shells (2, 3). The thick outer peripheral portion 4a of the diaphragm can be fitted between the outer peripheral portions of the diaphragm. This may be better understood by referring to FIGS. 2A and 2B, which are enlarged to compare the conventional apparatus with the apparatus of the present invention, respectively.

As is apparent from FIG. 2a, the annular groove 4b of the diaphragm outer circumferential portion 4a is substantially U-shaped in cross section and substantially the cross section of the annular projection 11 in which the second shell 3 is folded back on its own. Sized to match. The outer circumferential edge 4c of the groove 4B is formed to fit snugly to the flange portion 9 of the second shell 3, but the width of the outer circumferential edge 4c is the outer circumferential portion 4a of the diaphragm. It is slightly larger than the width of the flange portion 9 to ensure airtightness when axially fitted between the branch portion 9 and the radiation step portion 7 of the first shell 2.

In the assembled state, the outer circumferential edge 4c is in elastic contact with the annular projection 11 and the open end 2a of the first shell 2, and in particular, the enlarged diameter portion of the first shell 2 ( 8) is in outer circumference.

Furthermore, even when the diaphragm 4 is of a somewhat reduced diameter, the diaphragm 4 is stretched while expanding the thick outer peripheral portion 4a of the diaphragm so that the groove 4b is an annular projection of the second shell 3. By making it fit into (11), the diaphragm 4 can be reliably attached to the 2nd shell 3 ,.

On the other hand, in the conventional apparatus as shown in FIG. 2B, when the first and second shells are joined together, only the thick outer peripheral portion 4a is placed on the flange portion 9 of the second shell 3 There is only. In this case, the outer circumference of the thick outer circumference 4a may be displaced from the outer circumference of the second shell 3. When the first and second shells are joined together in this misaligned state, the thick outer periphery 4a is not completely received in the inner surface of the opening of the first shell 2. That is, the outer peripheral portion 4a is partially pushed outward and protrudes through the shell because the open end of the first shell pushes a portion of the outer peripheral portion outward. At the completion of the joining of these shells, a sufficient airtight structure cannot be obtained.

Therefore, as described above, according to the present invention, the engagement portion between the first and second shells can be obtained, which can increase the centering effect of the diaphragm when the diaphragm is not displaced and the coupling is achieved. In addition, in the thick outer peripheral portion 4a of the diaphragm, the annular groove 4b extends the diaphragm into the thick outer peripheral portion so as to engage the hybrid projection 11 and before the second shell is formed, the second shell is formed. By mounting the diaphragm in (3) in advance, it is possible to use a diaphragm having a diameter somewhat smaller than the diameter of each shell, and the thick outer periphery of the diaphragm is sandwiched between these shells.

While the invention has been particularly shown and described with reference to its preferred embodiments, it will be understood by those skilled in the art that various changes and modifications can be made therein without departing from the spirit and scope of the invention.

Claims (2)

In the diaphragm 4 in which the outer circumferential edge 4c is fitted between the first and second shells to form a fluid sealing chamber with respect to the housing 1 formed by the first and second cells 2, 3, The first shell 2 has a cup shape having an enlarged diameter portion 8 radially shortened at its open end 2a, and the second shell 3 is generally radially of the first shell 2. The outer peripheral edge 4c has an outer diameter corresponding to the inner diameter in the short binary enlarged diameter portion 8 and protrudes radially inward in the radially short binary enlarged diameter portion 8 of the first shell adjacent to the outer peripheral edge thereof. The diaphragm 4 has a thick outer peripheral portion 4a and a size and a position corresponding to the annular protrusion to receive the annular protrusion, and are formed in a disc shape ending in the retracted annular protrusion 11 of the outer peripheral portion 4a. A first for forming the sealed housing 1 by including an annular groove 4b formed in the surface And the thick outer periphery of the diaphragm so that the diaphragm is not displaced with respect to the first and second shells, even if there is an imbalance in the pressing force that can achieve the engagement of the second shell and the outer periphery of the first and second shells together. Diaphragm characterized in that the annular projection 11 of the second shell is fitted in the circular groove 4b in 4a) so that the thick outer peripheral portion 4a of the diaphragm can be inserted between the first and second shells. . In an improved sealing shell joint between the first and second shells 2, 3 defining the housing 1, such as a brake booster 10, the housing has an enlarged diameter radially shortened at the opening end 2a. The outer shell has a cup-shaped first shell 2 having a portion 8 and an outer circumferential edge 4c having the same diameter as the inner diameter in the radially shortened enlarged diameter portion 8 of the first shell. A second shell 3 in the form of a disk ending in a retracted annular projection 11 protruding inwardly inwardly, and a thick outer periphery 4a and a second of the same diameter as the inner diameter in the enlarged diameter portion of the first shell. An annular groove 4b having a size and a position corresponding to the annular projection 11 of the shell and formed in the surface of the thick outer peripheral portion 4a of the diaphragm 4 so as to receive the annular projection facing the annular projection 11. The housing 1 on each side while providing an airtight seal between the combined first and second shells. Sealing shell coupling, characterized in that consisting of a diaphragm defining a fluid sealing chamber for.

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