HUP0201553A2 - Hemispherical shoe - Google Patents

Description

PUBLICATION COPY

Hemispherical glide base

The invention relates to a hemispherical slide shoe having a convex semicircular surface fitted into a hemispherical seat formed in a first movable element and an end surface in sliding contact with a flat surface of a second movable element. The invention relates primarily to a hemispherical slide shoe which is located, for example, between the swash plate and the piston of a swash plate compressor.

A hemispherical slide having a hemispherical convex surface that fits into a hemispherical recess in a moving element, namely a piston, and an end surface that is in sliding contact with a flat surface of a swash plate, is well known in the art.

Furthermore, a hemispherical slide shoe having a diameter R2 of a convex hemispherical surface smaller than the diameter R1 of a seat formed in a piston rod by a predetermined amount is also well known (see, for example, Japanese Utility Model Application No. 5,259/1995).

This known solution proposes a hemispherical sliding base, in which the convex hemispherical surface of the sliding base and the hemispherical shape of the socket receiving the sliding base are dimensioned in such a way that a gap remains free between the inlet region of the hemispherical socket of the piston and the convex hemispherical, opposing surface of the sliding base. Thanks to this, lubricant, oil, can be introduced into the gap through the inlet of the hemispherical socket, which, entering between the surfaces of the convex hemispherical surface and the hemispherical socket of the piston, which are in frictional contact with each other, exert a lubricating effect proportional to the tilting angle of the swash plate during the movement of the sliding base.

In this known hemispherical slide, the upper region of the convex hemispherical surface is machined to obtain a flat surface, which thus results in a space of curved cross-section between the flat surface of the hemispherical slide and the opposing surface of the hemispherical seat of the piston. The purpose of this is to allow this space to act as a lubricating oil reservoir, thereby allowing the lubricating oil to enter in an appropriate amount between the convex hemispherical surface of the slide and the hemispherical seat of the piston during operation of the structure.

-2However, it should be mentioned as a shortcoming of the proposed and known solution that the flat surface of the hemispherical sliding pad is at an acute angle to the hemispherical surface of the piston, which significantly reduces the volume of the gap between the flat surface and the seat. The consequence of this is that the lubricating oil stored here does not penetrate as much between the surfaces of the hemispherical sliding pad and the hemispherical seat that are in frictional contact with each other.

In addition, another shortcoming is that after the hemispherical sliding pad and the hemispherical seat of the piston wear together during operation, the contact surfaces of the hemispherical sliding pad and the hemispherical seat grow so large that not enough lubricant or oil can reach the inside of the friction surfaces to ensure proper lubrication, especially in cases where the sliding pad only moves slightly or the swash plate tilts slightly.

Our aim with the invention is to reduce the shortcomings experienced in known hemispherical sliding feet.

The task was solved on this basis by a hemispherical slide base having a convex semicircular surface fitted into a hemispherical nest formed in a first moving element and an end surface in sliding contact with a flat surface of a second moving element. According to our invention, the convex hemispherical surface in sliding contact with the hemispherical nest formed in the first moving element is formed by a body of revolution produced by rotating a circular arc with a center point at a defined distance perpendicular to the axis of symmetry of the hemispherical slide base around the axis of symmetry of the hemispherical slide base as an axis of rotation.

With the proposed design, the upper region of the convex hemispherical surface of the hemispherical sliding pad is not connected to the hemispherical seat of the piston at an acute angle, but rather with an edge of curved cross-section, as a result of which a suitable gap remains between the upper region of the hemispherical sliding pad and the opposing hemispherical seat of the piston, which gap has a wedge cross-section. This allows the lubricating oil stored in the space formed between the upper region of the convex hemispherical surface and the opposing part of the first moving element, i.e. the piston hemispherical seat, to reliably and in sufficient quantity reach the convex hemispherical surface and the surface of the piston hemispherical seat through this wedge-shaped gap. This ensures excellent sliding properties and a long service life of the hemispherical sliding pad.

-3 In addition, we were able to reduce the contact between the hemispherical nest formed in the first moving element and the convex hemispherical surface of the hemispherical slide base compared to known hemispherical slide base solutions, which allows the lubricating oil to reach the frictional and sliding contact surfaces efficiently and in sufficient quantity, even if the hemispherical slide base only moves a small amount or if the tilt angle of the second moving element is small.

According to a preferred embodiment of the proposed hemispherical slide base, the difference between the radius of the recess formed in the first moving element and the radius of the convex surface of the slide base exceeds 150 μm.

Also preferred is an embodiment of the hemispherical slide base according to the invention in which the distance of the center of the body of rotation from the axis of symmetry of the slide base, measured perpendicular thereto, is selected to be in the range of 20-500 μιη.

The invention is described in more detail below with the aid of the attached drawing, which shows an exemplary embodiment of the proposed hemispherical sliding base. In the drawing,

Figure 1 is a schematic cross-section of a possible embodiment of the hemispherical sliding base according to the invention, and

Figure 2 shows a detail of Figure 1 on a larger scale.

In Fig. 1, an embodiment of the hemispherical sliding base 1 according to the invention, which is considered to be a preferred example, is outlined, for example, in a swash plate compressor. The compressor thus has a hemispherical sliding base 1, a piston 2 performing vertical alternative movement in the directions shown in Fig. 1, and a flat swash plate 3 rotated by a stem. A hemispherical seat 2B is machined into the end surface 2A of the piston 2. In the case of the embodiment shown, the radius R1 of the hemispherical seat 2B is the same throughout the entire length of the seat 2B.

The hemispherical slide 1 has a convex hemispherical surface 1A and a flat end surface 1B. In the upper region of the slide 1 shown in FIG. 1, the convex hemispherical surface 1A is formed as a non-contacting region IC which is not in contact with the hemispherical seat 2B of the piston 2. In the end surface 1B of the slide 1, or in the region around the axis of symmetry L of the slide 1, a substantially conical recess 1D is formed.

-4A The hemispherical convex surface 1A of the hemispherical sliding base 1 fits into the hemispherical seat 2B of the piston 2, while its end surface 1B is in contact with the swash plate 3. If the hemispherical sliding base 1 is located between the hemispherical seat 2B and the swash plate 3, then a section of the convex hemispherical surface 1A of the sliding base 1 extends in the boundary area 1E between the hemispherical surface 1A and the end surface 1B of the sliding base 1, adjacent to the latter, which extends opposite the edge 2A' of the hemispherical seat 2B extending in the space between the end surface 2A of the piston 2 and the swash plate 3. This edge 2A' defines the entrance to the hemispherical seat 2B.

A space 4 is formed between the non-contact IC region and the opposing hemispherical seat 2B of the piston 2, and a space 5 is formed between the swash plate 3 and the recess 1D. The spaces 4, 5 provide temporary storage for the lubricating oil.

A wedge-shaped gap 6 is formed between the region adjacent to the edge 2A' of the hemispherical socket 2B, which defines the entrance, and the convex hemispherical surface 1A opposite thereto. Accordingly, in the embodiment shown, the region of the convex hemispherical surface 1A of the slide base 1, which is closer to the non-contacting region IC, or to the gap 4, than the gap 6, forms the cross-hatched sliding surface 1F in FIG. 1 with respect to the hemispherical socket 2B.

When the swash plate 3 is rotated, the piston 2 is forced to reciprocate vertically by the hemispherical slide 1. In this process, a sliding movement is formed between the end surface 1B of the hemispherical slide 1 and the swash plate 3, and the sliding surface 1F of the convex hemispherical surface 1A also performs a sliding movement with respect to the hemispherical seat 2B of the piston 2. During this operation, the lubricating oil enters the gap 6 through the rim 2A', up to between the sliding surface 1F of the convex hemispherical surface 1A and the surface of the hemispherical seat 2B. In addition, the lubricating oil previously stored in the aforementioned space 4 enters between the sliding surface 1F of the convex hemispherical surface 1A and the surface of the hemispherical seat 2B, thereby cooling the contacting, sliding and frictional portions. Finally, the lubricating oil stored in the space 5 enters between the end surface 1B and the frictional portions of the swash plate 3, thereby also cooling the contacting portions.

Alternatively, an opening similar to the 1D recess formed in the end surface 1B may be provided.

-5• · ····· · • * · ··· 4 ·« « last can be formed centrally in the contactless IC region, or on top of the convex hemispherical surface 1A.

In the case of the presented embodiment, in order to facilitate the delivery of the lubricating oil stored in the space 4 to the sliding surface 1F of the convex hemispherical surface 1A, the convex hemispherical surface 1A of the hemispherical sliding base 1 according to the invention can be formed in the following manner.

In particular, in the case of the embodiment shown, it can be observed that the convex hemispherical surface 1A is defined by the convex surface of a body of revolution which is obtained when a circular arc of radius R2, the center C of which is located at a given distance perpendicular to the axis of symmetry L of the hemispherical slide 1, is rotated about the axis of symmetry L of the hemispherical slide 1 as the axis of rotation. The contact-free region IC is formed by the upper part of the body of revolution. The cross-section of this contact-free region IC is slightly curved, but it can also be bounded by a flat surface which extends in a plane perpendicular to the axis of symmetry L of the slide 1.

In the case of the embodiment shown, the radius R2 of the circular arc is chosen to be smaller than the radius R1 of the hemispherical socket 2B. The difference between the radius R1 and the radius R2 is chosen to be greater than 150 μm, as is typical of the invention. Furthermore, in the case of the embodiment shown, the distance by which the center C is displaced horizontally relative to the vertical axis of symmetry L of the slide 1 is chosen to be in the range of 20-500 μm.

The result is outlined in the enlarged detail of Figure 2, where it can be observed that a curved cross-section leading part 1G is formed at the boundary between the non-contact IC region and the sliding surface 1F. If such a leading part 1G is created, then a further 7 gaps with a wedge cross-section and increasingly narrowing towards the sliding surface 1F are created between the leading part 1G and the hemispherical nest 2B.

In the case of the embodiment shown, the distance of the sliding surface 1F from the symmetry axis L is chosen to be smaller, whereby the outer edge of the end surface 1B in sliding contact with the swash plate 3 extends further from the symmetry axis L. In other words, the sliding surface 1F is formed to be closer to the symmetry axis L than the outer peripheral point of the end surface 1B, thereby facilitating the swinging movement of the hemispherical sliding base 1.

-6The extent of the sliding movement of the IF sliding surface relative to the hemispherical seat 2B was chosen so that, when compared to the axis of the hemispherical seat 2B of the piston 2 and centered on the center O of the radius R1 of the hemispherical seat 2B, the 1F sliding surface performs a sliding movement of 60°, preferably in the range of 5-60°, more preferably in the range of 20-40°, relative to the axis of the hemispherical seat 2B.

If the convex hemispherical surface 1A of the hemispherical slide 1 is formed as described above to form the leading part 1G towards the gap 4, the lubricating oil stored in the gap 4 can be supplied to the sliding surface 1F through the gap 7 and cooled to a very advantageous and adequate extent. Accordingly, the slide 1 according to the invention provides adequate cooling for the sliding surface 1F through the lubricating oil and also has very good sliding properties, which significantly increases the service life of the slide 1 compared to known solutions.

Furthermore, in connection with the presented embodiment, also compared to known solutions, we were able to significantly reduce the contact area between the convex hemispherical surface 1A of the hemispherical sliding base 1 and the hemispherical seat 2B of the piston 2, so that the lubricating oil can be delivered effectively and in an adequate amount to the sliding surface 1F of the sliding base 1 and to the seat 2B of the piston 2, not only to their edges but also towards their center, even in the case where the amplitude of the swinging movement of the sliding base 1 is small or if the tilting angle of the swash plate 3 is small.

In the embodiment of the hemispherical sliding base according to the invention shown in the figures, the parts of the convex hemispherical surface 1A outside the contact-free IC region were implemented with a convex surface that was given using the radius R2, but at least a region of the sliding surface 1F of the sliding base 1 can also be implemented with a convex surface that can also be defined using the radius R2.

From the above, it can be seen that the hemispherical sliding base according to the invention has good gliding and sliding properties and a long service life, and its industrial applicability is advantageous.

Claims (3)

• · ····· · « ··· ··· · ·« -7 Patent claims 1. A hemispherical slide base having a convex semicircular surface fitted into a hemispherical seat formed in a first moving element and an end surface in sliding contact with a flat surface of a second moving element, characterized in that the convex hemispherical surface (1A) in sliding contact with the hemispherical seat (2B) formed in the first moving element is formed by a body of revolution produced by rotating the hemispherical slide base (1) around the axis of symmetry (L) of the hemispherical slide base (1) as an axis of rotation, with a center (C) defined at a defined distance perpendicular to the axis of symmetry. 2. A hemispherical slide base according to claim 1, characterized in that the difference between the radius (R1) of the recess (2B) formed in the first moving element and the radius (R2) of the convex surface of the slide base (1) exceeds 150 µm. 3. A hemispherical slide base according to claim 1 or 2, characterized in that the distance of the center of the body of rotation (C) from the axis of symmetry (L) of the slide base (1), measured perpendicular thereto, is chosen to be in the range of 20-500 gm. The authorized person: DANUBE Patent and Trademark Office Ltd. Dr. Andras Antalffy-Zsíros