GAS OR FLUID TRANSFER SYSTEM WITH DOUBLE ABSORPTION COMPRESSION APPARATUS AND DOUBLE CHAMBER

The present invention relates to the fact that

The double absorption compression wobbles/oscillates by contacting the wobbling wall in the left chamber and the right chamber in the body, with the power it receives from the engine,

The gas or fluid coming from the absorption pipe enters both the left chamber and the right chamber,

As a result of the pressure exerted by the double elliptical disk by oscillating, the gas or fluid coming out of both the left chamber and the right chamber exits the compression pipe,

As a result of the wobbling of the absorption and compression apparatus in the left chamber and the right chamber, the absorption and compression processes of the absorbed and compressed gas/fluids being carried out simultaneously and continuously, the absorption and compression processes being not interrupted and that compressing as much gas/fluid as the gas/fluid it absorbs "in a gas or fluid transfer system with absorption and compression feature, which has a double (two) absorption-compression apparatus and a body with a left chamber and a right chamber into which they fit"

State of the art:

In patent applications no. 2016/16803, 2017/00888, 2018/15205, 2018/15836, 2019/20995 and 2019/20652 on behalf of Hamit Aykag;

An assembly/pump/vacuum machine/device is described in which one absorption compression apparatus (wobbling apparatus) is rotated in a single body chamber with the help of an engine and oscillates in a horizontal position by contacting the wobbling wall and taking the gas/fluid from the absorption pipe to the absorption area of the body and from there to the compression area and compressing the same into the compression pipe.

Since there is a balance problem during the operating phase of the system with a single absorption and compression apparatus in a single body chamber, a pump/vacuum machine with double (two) absorption and compression apparatus in two chambers in a single body has been developed. Aim of the Invention:

The aim of the present invention is to prevent shaking during operation, to eliminate the balance problem, to increase the amount of absorbed and compressed gases and/or fluids by developing a transfer system/pump/vacuum machine with a double absorption compression apparatus that oscillates in two chambers in a single body.

The present invention is characterized by the following;

1 -Having two chambers (left chamber and right chamber) in a single body,

2-Comprising the absorption pipe inlet port to which the absorption pipe is connected on the left and right of the body, and the compression pipe inlet port to which the compression pipe is connected,

3 -Having a left chamber spindle inlet hole in the left chamber where the spindle will enter, and there is a right chamber spindle inlet hole in the right chamber where the spindle will enter,

4-The suction pressure apparatus consisting of an elliptical disk positioned between two spheres placed on the shaft on the spindle,

5 -Having a left chamber spindle inlet hole in the left chamber (where the spindle will enter, and there is a right chamber spindle inlet hole in the right chamber where the spindle will enter),

6- Forcing elliptical disks on rotating spindles so as to make circular motion with the help of an engine,

7-Elliptical disks that come into contact with the concave face of the wobbling wall not being able to make circular movements but oscillating/wobbling,

8-As a result of the wobbling of the elliptical disks, advancing the gas or fluids coming from the absorption pipe to the compression pipe with the compression applied in the chamber.

The figures prepared for a better understanding of the present invention are as follows;

Figure 1 -Perspective view of the parts forming the absorption compression apparatus in disassembled position,

Figure 2-Perspective view of the sphere from the left side,

Figure 3 -Perspective view of the sphere from the right side,

Figure 4- Disassembled perspective view of the elliptical disk,

Figure 5-Assembled perspective view of the two parts of the elliptical disk, Figure 6-Perspective view of the absorption compression apparatus without the elliptical disk,

Figure 7-Front view of the absorption compression apparatus without the elliptical disk, Figure 8-Perspective view of the elliptical disk and the sphere in the disassembled position in the absorption compression apparatus,

Figure 9-Perspective view of the elliptical disk and the sphere in the assembled position in the absorption compression apparatus,

Figure 10-Perspective disassembled view of the two parts forming the body,

Figure 11 -Perspective assembled view of the two parts forming the body,

Figure 12-External perspective view of the right body chamber,

Figure 13 -Front view of the right body chamber,

Figure 14-Perspective view of the right body chamber in disassembled position with the wobbling wall,

Figure 15 -Perspective view of the absorption compression apparatus in disassembled position with the wobbling wall,

Figure 16-Perspective view of the absorption compression apparatus in contact with the wobbling wall,

Figure 17 -Perspective view of the double absorption compression apparatus with the wobbling wall in a disassembled position on the half body,

Figure 18-Perspective view of the double absorption compression apparatus with the wobbling wall in an assembled position on the half body,

Figure 19-Perspective view of the double absorption compression apparatus with the wobbling wall attached, in a half-body assembled position, and in a disassembled position with the absorption pipe and compression pipe,

Figure 20-Perspective view of absorption compression apparatus, absorption pipe and compression pipe assembled on the body,

Figure 21- Disassembled perspective view of the parts forming the engine and gear housing,

Figure 22- Disassembled perspective view of the parts forming the engine and gear chamber, Figure 23 -Perspective view of the two gears rotated by the gear spindle,

Figure 24-Perspective view of the gear chamber with engine attached, disassembled with the body,

Figure 25-Perspective view of the gear chamber with engine attached, assembled with the body, Figure 26- Sectional perspective view of the first stage of the operation of the absorption compression apparatus in the left chamber and the right chamber,

Figure 27- Sectional perspective view of the second stage of the operation of the absorption compression apparatus in the left chamber and the right chamber,

Figure 27-Front sectional view of the first stage of the contact of the elliptical disk on the left and the elliptical disks on the right to the wobbling wall in the opposite direction,

Figure 28-Front sectional view of the second stage of the contact of the elliptical disk on the left and the elliptical disks on the right to the wobbling wall in the opposite direction,

Figure 30-Top view of the elliptical disk on the left and the elliptical disks on the right contacting the wobbling wall in the opposite direction.

For a better understanding of the present invention, each part in the figures prepared is individually numbered. The description of each numbered part is as follows;

1 -Absorption pressure apparatus,

1.1 -Shaft,

1.2-Sphere,

1.2.1-Shaft transition channel,

1.2.2-Fixing tab,

1.2.3-Disk seating surface,

1.2.4-Contact surface to the other sphere,

1.3 -Elliptical disk,

1.3.1-Staggering wall seating area,

1.3.2-Disk tab,

1.3.2.1-Tab fixing hole,

1.3.3 -Disk tab slot,

1.3.4-Disk tab clamping hole,

1.3.5-Shaft clutch channel,

2-Spindle,

3-Wobbling wall,

3.1 -Concave surface,

4-Body,

4.1 -Left chamber,

4.2-Right chamber,

4.3 -Left chamber spindle inlet hole, 4.4-Right chamber spindle inlet hole,

4.5 -Ab sorption pipe inlet port,

4.6-Compression pipe inlet port,

4.7-Chamber connection hole,

4.8-Wobbling wall inlet channel,

5-Absorption pipe,

6-Compression pipe,

7-Engine,

7.1 -Engine spindle,

8-Gear chamber,

8.1 -Front cover,

8.1.1 -Front cover spindle inlet hole,

8.2-Rear cover,

8.2.1-Spindle inlet hole to the left chamber,

8.2.2-Spindle inlet hole to the right chamber,

8.3 -Gear spindle,

8.4-Gear,

8.4.1 -Ab sorption compression apparatus spindle inlet hole,

8.5 -Bearing,

8.6-Seal,

9-Connection apparatus to the gear spindle,

9.1 -Connection apparatus inlet hole

Absorption compression apparatus (1) is described in the patent applications numbered 2016/16803, 2017/00888, 2018/15205, 2018/15836, 2019/20995 and 2019/20652 in the name of Hamit Aykat? as a single absorption compression apparatus and the mechanism containing the single-chamber body into which it fits.

In this description, the transfer system/mechanism/pump consisting of the double (two) absorption compression apparatus (1) and the double body (4) consisting of the left chamber (4.1) and the right chamber (4.2), into which the two absorption compression apparatus (1) enter, has been described. The perspective view of the parts forming the absorption compression apparatus (1) in disassembled position is given in figure 1.

The absorption compression apparatus (1) consists of two spheres (1.2) positioned opposite each other on a shaft (1.1) and an elliptical disk (1.3) positioned between the spheres (1.2).

Perspective view of the sphere (1.2) from the left side is given in figure 2, Perspective view of the sphere (1.2) from the right side is given in figure 3.

In the middle of the sphere (1.2), there is the shaft transition channel (1.2.1) through which the shaft (1.1) passes, the fixing tab (1.2.2) that fixes the shaft (1.1), and the disk seating surface (1.2.3) on which the elliptical disk (1.3) sits and there is a contact surface (1.2.4) with the other sphere at its end.

Disassembled perspective view of the elliptical disk (1.3) is given in figure 4,

Assembled perspective view of the two parts of the elliptical disk (1.3) is given in figure 5, The elliptical disc (1.3) is symmetrical in appearance and has two parts. The upper part has wobbling wall seating area (1.3.1), at both ends there are disk tabs (1.3.2) and the disk tabs (1.3.2) have a tab fixing hole (1.3.2.1).

The lower part has disk tab slots (1.3.3) and disk tab clamping holes (1.3.4).

Disk tabs (1.3.2) are inserted into the disk tab slots (1.3.3) and fixed with screws or similar equipment.

A shaft clutch channel (1.3.5) is formed between the two symmetrical parts, through which the shaft (1.1) will pass.

Perspective view of the absorption compression apparatus (1) without the elliptical disk (1.3) is given in figure 6,

Front view of the absorption compression apparatus (1) without the elliptical disk (1.3) is given in figure 7.

Shaft (2) is inserted into the spindle (1.1).

Perspective view of the elliptical disk (1.3) and the sphere (1.2) in the disassembled position in the absorption compression apparatus (1) is given in figure 8,

Perspective view of the elliptical disk (1.3) and the sphere (1.2) in the assembled position in the absorption compression apparatus (1) is given in figure 9.

The body (4) consists of two symmetrical parts that can be assembled together.

Perspective disassembled view of the two parts forming the body (4), is given in figure 10, Perspective assembled view of the two parts forming the body (4), is given in figure 11.

The body (4) consists of the left chamber (4.1) and the right chamber (4.2). There is a left chamber spindle inlet hole (4.3) in the left chamber (4.1), and a right chamber spindle inlet hole (4.4) in the right chamber (4.2). Between the left chamber (4.1) and the right chamber (4.2), there is an absorption pipe inlet port (4.5) to which the absorption pipe (5) that carries the gas or fluid in is connected and a compression pipe inlet port (4.6) to which the compression pipe (6) that discharges the absorbed gas or fluid out is connected.

Two symmetrical body (4) parts are connected to each other using screws or similar connection devices through the chamber connection holes (4.7).

External perspective view of the right chamber (4.2) of the body (4) is given in figure 12, Front view of the right chamber (4.2) of the body (4) is given in figure 13.

The wobbling wall inlet channel (4.8), where the wobbling wall (3) enters, the absorption pipe inlet port (4.5) and the compression pipe inlet port (4.6) are shown in section.

Perspective view of the right chamber (4.2) of the body (4) with the wobbling wall (3) in the disassembled position is given in Figure 14.

The wobbling wall (3) is inserted into the wobbling wall inlet channel (4.8) in a vertical position. The side surfaces of the wobbling wall (3) are designed as concave walls (3.1) since they are the surfaces that the elliptical disk (1.3) will contact.

Perspective view of the absorption compression apparatus (1) with the wobbling wall (3) in the disassembled position is given in figure 15,

Perspective view of the absorption compression apparatus (1) in contact with the wobbling wall (3) is given in figure 16.

Perspective view of the double absorption compression apparatus (1) with the wobbling wall (3) in a disassembled position on the half body (4), is given in figure 17.

Perspective view of the double absorption compression apparatus (1) with the wobbling wall (3) in an assembled position on the half body (4), is given in figure 18.

The spindle (2) connected to the upper absorption compression apparatus (1) enters from the left chamber spindle inlet hole (4.3),

The spindle (2) connected to the absorption compression apparatus (1) at the bottom enters the right chamber spindle inlet hole (4.4). The wobbling wall (3) also enters the wobbling wall inlet channel (4.8) shown in Figure 14 and Figure 17. It forms two separate sections: left chamber (4.1) and right chamber (4.2).

The suction pipe (5) is mounted on the absorption pipe inlet port (4.5) on the body (4) and the compression pipe (6) is mounted on the compression pipe inlet port (4.6).

Perspective view of the double absorption compression apparatus (1) with the wobbling wall (3) in an assembled position on the half body (4), and in a disassembled position with the absorption pipe (5) and compression pipe (6) is given in figure 19,

Perspective view of the absorption compression apparatus (1), absorption pipe (5) and compression pipe (6) assembled on the body (4) is given in Figure 20.

Disassembled perspective view of the parts forming the engine (7) and the gear chamber (8) is given in figure 21,

Assembled perspective view of the engine (7) and gear chamber (8) is given in Figure 22. There is an engine spindle (7.1) connected to the engine (7).

The gear chamber (8) consists of the front cover (8.1) and the rear cover (8.2). There is a front cover spindle inlet hole (8.1.1) on the front cover (8.1).

The gear chamber (8) contains two gears (8.4), bearing (8.5) and seal (8.6).

After the bearing (8.5) and seal (8.6) are installed on the gear spindle (8.3), the front cover is inserted through the spindle inlet hole (8.1.1) from one side, and the connection apparatus is inserted through the inlet hole (9.1) and connected to the gear spindle connection apparatus (9). The absorption compression apparatus is passed through the spindle inlet hole (8.4.1), connected to the gear (8.4) and passed to the spindle inlet hole (8.2.1) leading to the left chamber on the front cover (8.2).

Perspective view of the two gears (8.4) rotated by the gear spindle (8.3) is given in Figure 23. Two gears (8.4) are connected to each other. The gear spindle (8.3) is inserted into the upper gear (8.4) from one side and the spindle (2) from the other side. A spindle (2) is inserted into the lower gear (8.4) from one side.

After the front cover (8.1) and the rear cover (8.2) are connected to each other, the outer gear spindle (8.3) is connected to the gear spindle connection apparatus (9) from its end. The engine spindle (7.1) is connected to the gear spindle connection apparatus (9) through the connection apparatus inlet hole (9.1). There is a spindle inlet hole (8.2.1) leading to the left chamber and a spindle inlet hole (8.2.2) leading to the right chamber on the rear cover (8.2).

The spindles (2) in the body (4) are inserted into the spindle inlet hole (8.2.1) leading to the left chamber, and into the spindle inlet hole (8.2.2) leading to the right chamber.

Disassembled perspective view of the gear chamber (8) with the engine (7) attached and the body (4) is given in figure 24,

Assembled perspective view of the gear chamber (8) with the engine (7) attached and the body (4) is given in figure 25.

Operation of fluid transfer pump:

When the engine (7) starts, the engine spindle (7.1) starts to rotate, (figure 21, figure 22).

The rotating engine spindle (7.1) starts to rotate the gear spindle connection apparatus (9) into which it enters and rotates the gear spindle (8.3) inside. The rotating gear spindle (8.3) rotates the gear (8.4) into which it is inserted. The rotating gear (8.4) also rotates the gear (8.4) to which it is connected.

Rotating gears (8.4) rotate the spindles (2) to which they are connected from the rear cover

(8.2).

Sectional perspective view of the first stage of the operation of the absorption compression apparatus (1) in the left chamber (4.1) and the right chamber (4.2), is given in figure 26, Sectional perspective view of the second stage of the operation of the absorption compression apparatus (1) in the left chamber (4.1) and the right chamber (4.2), is given in figure 27.

When the sphere (1.2) and the elliptical disk (1.3) contact the wobbling wall (3) and oscillate, two separate sections are temporarily formed in the left chamber (4.1) and the right chamber

(4.2). In Figure 26, when the elliptical disk (1.3) touches the wobbling wall (3) and tilts to the right, gas or fluid fills the space formed at the top of the left chamber (4.1) from the absorption pipe inlet port (4.5). As the shaft (2) continues to rotate and the elliptical disc

(1.3) and the left chamber (4.1) tilt to the left, a gap is created at the bottom of the left chamber (4.1). The compressed gas/fluid is directed from this gap to the discharge pipe inlet port (4.6). They are shown with dashed arrows in Figure 26 and Figure 27. The elliptical disc (1.3) in the absorption compression apparatus (1) in the right chamber (4.2) rotates in the opposite direction of the elliptical disk (1.3) in the absorption compression apparatus (1) in the left chamber (4.1). Gas or fluid coming from the absorption pipe inlet port (4.5) and entering the space on the right side of the lower chamber (4.2) (Figure 27), exits from the compression pipe inlet port (4.6) when the elliptical disk (1.3) changes direction by contacting the wobbling wall (3). This movement is shown with dotted arrows in Figure 27 and Figure 26.

Front sectional view of the first stage of the contact of the elliptical disk (1.3) on the left and the elliptical disks (1.3) on the right to the wobbling wall (3) in the opposite direction is given in figure 28,

Front sectional view of the second stage of the contact of the elliptical disk (1.3) on the left and the elliptical disks (1.3) on the right to the wobbling wall (3) in the opposite direction is given in figure 29.

Top view of the contact of the elliptical disk (1.3) on the left and the elliptical disks (1.3) on the right to the wobbling wall (3) in the opposite direction is given in figure 30.

The body (4) and the absorption compression apparatus (1) may be made of metal or plastic.