DE3336406A1 - CIRCULATING LIQUID MOTOR FOR A THERMODYNAMIC MEDIUM - Google Patents

Description

- 3 - U.Z.820.44

SORELEC

La Motte Saint Euverte

Saint Jean De Braye (Loiret)

France

Rotating fluid motor for a thermodynamic medium

The invention relates to a rotating fluid motor for a thermodynamic medium, with a group of common rotating units, each of which consists of two diametrically opposed rigid subsets of constant volume that contain a thermodynamic medium that alternates evaporates and condenses, depending on whether the corresponding subgroup is exposed to a heat source or exposed to a source of cold.

In particular, the invention relates to a solar motor, which the thermodynamic energy with the help of a in permanent equilibrium (Vapor-liquid) located thermodynamic Medium in a closed PC cycle, as well as a second medium (Water, oil, etc.) or a tilting part into mechanical and electrical energy.

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Devices of the type mentioned are known which convert the thermodynamic energy into mechanical energy effect, be it by evaporation of a liquid or with With the help of a gas engine using the Carnot cycle.

However, both of these types of devices currently on the market are expensive; that gas engines need especially complicated systems (collector, condenser, expansion machine, injection pump, etc.).

Apart from the resulting very high investment costs, these systems require constant technical monitoring. Otherwise, they only have a mediocre degree of efficiency. Certain embodiments are technical gadgets because they cannot be industrialized. These technical gadgets are based on the following principle:

An evaporating liquid increases the pressure of the container; this pressure causes a liquid to rise in an equilibrium arrangement, whereby the entire device tilts and returns to its original position. This has become known as "duck" (canard).

The invention is based on the object of creating a rotary motor of the type mentioned above which is capable of to create a relatively significant power to drive a consumer device whose operation by the Imbalance of. corresponding chambers is not immediately disturbed.

This task * is achieved according to the invention in that each Subset consists of a deformable sealed chamber containing a thermodynamic medium as well as a heavy transmission device contains that immediately and completely each

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Changes in volume of one of the cans transfers to the other chamber, whereby the transmission device thus assumes a position with disturbed equilibrium and generates a torque, which is transmitted to the shaft of the motor.

In another embodiment of the invention, the transmission device is either a unit of two pistons,
which are connected to one another by a connecting part provided with a heavy mass or by a column of liquid.

The two pistons can also be formed by elastic partitions or pockets.

At rest, when the temperature of the cold source is the same

that of the heat source, the device is' in equilibrium: the masses of the thermodynamic medium contained in the two chambers are the same, and the heavy one The transmission part is in a state of equilibrium.

Only through the displacement of the heavy transmission part under the action of the diametrically opposite one in the two chambers Subgroups of each rotary unit prevailing pressure difference, this imbalance creates a torque that attacks on the output shaft of the motor.

Exemplary embodiments of the invention are illustrated using the figures explained in more detail. It shows:

Fig. 1 is a schematic representation of an engine according to the invention,

Fig. 2 shows a section along the line II-II in Fig. 1,
FIG. 3 shows a section along the line ITI-TJI in FIG. 1

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4 shows a schematic perspective illustration of another / embodiment of the invention,

5 shows a section through the central plane of the embodiment

of Fig. 4,
5

6 shows a schematic representation of an embodiment a tunnel and

7 shows a schematic representation of another embodiment of a tunnel.

As can be seen from Fig. 1, the rotating fluid motor is seated for a thermodynamic medium composed of a number of subgroups 1, each of which consists of two chambers

2, 3, which are connected to one another, e.g. by a radial arm 4, which at the same time forms a connecting pipe.

Each chamber 2, 3 contains a pocket 5, 6; the two pockets of the two corresponding chambers are connected to the pipe 4

connected to each other. The volume delimited in each case between each chamber 2, 3 and the corresponding pocket 5, 6 is tightly sealed and contains a thermodynamic medium, i.e. a medium that is at the temperature of the heat source SC evaporated and condensed at the temperature of the cold source SF

sated. As the temperatures of the heat source SC and the cold source SF depend on the conditions of use, the thermodynamic medium is chosen accordingly.

The unit formed by the two pockets 5 _r 6 and the tube 4 forms a closed constant volume, are being formed through pockets 5, 6, two deformable parts. Any reduction in the volume of one of the pockets 5, 6 has the effect of increasing the volume of the other pocket 6.5, since the closed volume is a non-compressible one

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Contains medium, preferably a liquid such as water or a liquid of higher density.

All of the rotating units 2, 3 are firmly connected to an output shaft 7. Because the torque exerted by each turntable depends on the weight difference between the two pockets 5, 6, the heat source SC acts on a vertical half of the device and the cold source SF acts on the other vertical half of the device.

The shaft 7 contains as many rotating units in each plane as the dimensions of the chambers 2, 3 allow. Several rotating units can be arranged next to one another on a common shaft.

In one embodiment, the heat source SC consists of one annular channel with a circular cross-section and corresponds to a ring half. This channel 8 absorbs solar radiation. The cold source SF also consists of a channel 9 with a circular cross-section and corresponds to one half of the ring. The channels of the heat source and the cold source 8, 9 correspond in fact to the same annular surface.

The channel 8 of the heat source consists of a sheath 10 which forms a heat-absorbing member and a transparent one Shell 11 is surrounded, which creates a greenhouse effect.

The channel 9 of the cold source has an outer wall 12 e.g.

made of felt, which is sprinkled with water that is produced by evaporation

Removes heat and allows cooling of the channel and thus the chambers as they pass through the channel.

The movement can also be accelerated by a chimney effect with circulation of hot and cold gases in the two channels, with connections for cold and hot air 13, 1-4 and corresponding

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Air outlets 15, 16 are provided, e.g. for in the ground Installed pipes or shafts that deliver hot or cold air, depending on whether the environment is used as a heat source or as a The cold source is used and the shaft laid in the ground accordingly represents the cold source or the heat source.

Finally · the device can be used with any other natural. Energy recovery system to be connected.

FIG. 2 is a section along the line II-II of FIG. 1 and shows the structure of the device in the region of the heat source, the channel of which works with greenhouse effect. This section shows the transparent outer shell H ₁ - which contains a layer of air, as well as the absorption material of the heat absorber 10, which forms the channel 8 through which the chambers 2, 3 pass. The chambers 2, 3 of each rotating unit, which are preferably spherical or rectangular in shape and made of a very thermally conductive material such as copper or aluminum, contain the deformable shell 5, 6, which is made of a preferably poorly thermally conductive material, in order to exchange heat or cold with the non-compressible medium.

FIG. 3 shows the structure of the device from FIG. 2 in the area of the cold source SF, and thus the structure of the opaque liquid-absorbing sheath 12, e.g. made of felt, which covers the Channel 9 delimits which is traversed by the chambers 2, 3.

As can be seen from Fig. 2 and 3, the seal between the tubes 4, which _{carry the chambers 2 r} 3, and the channel of the heat source and the cold source 8, 9 is ensured by strippers 17.-. This sealing can also be done in another way, in that the radial tubes 4 are replaced by a rotor or by at least on the outside of the tubes 4 in the area of their passage through the channels of the heat source and the cold source 8, 9 a ring is attached, which the

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Sealing by sliding or rolling contact with those assigned in the channels of the heat source and the cold source 8, 9 Sealing parts takes over.

To take advantage of the rising flow of hot and cold gas in the channels of the heat source and the cold source, it is advantageous to provide the chambers at least partially with blades 18 in order to transfer the movement to improve.

Finally, the heat source can be replaced by a basin that is heated by solar radiation or contains warm withdrawal water, and in which the chambers are immersed one after the other to warm up, being the source of cold is formed by the environment outside the pelvis.

The engine shown in Figs. 4 and 5 consists of a Stator 20 and a rotor 21.

.20 The stator 20 has the shape of an annular tunnel (cf. Figs. 6 and 7), with an insulating sleeve 22, e.g. with a rectangular, square or circular cross-section surrounding a chamber 23 in which a heat exchange medium flows, and a chamber 24 in which a cooling medium flows. Each of the chambers 23, 24 corresponds essentially to a semicircle.

The rotor 21 rotates within the free volume delimited by the chambers 23, 24.

In a first embodiment (sub-groups 25, 26) the rotor from a number of sub-groups, which have an elastic partition wall 27, which the chambers 28, 29 or 30, 31 limited.

The chambers 28, 30 contain a thermodynamic medium, that at the temperatures of the heat source or the cold source

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clc-'iö motor evaporates or condenses.

The chambers 29, 31 are connected to one another by a channel 32, and the entirety of the volume thus enclosed contains a liquid whose boiling point is significantly higher than the temperature of the heat source.

The liquid is thus partly drawn from the chamber (e.g. 29) on the side of the heat source towards the chamber 31 pushed back on the side of the cold source, which disturbed the equilibrium of the subgroup and created a torque is generated, which acts on the output shaft of the engine.

Fig. 5 shows the deformation and the position of the two partition walls 27; in this example the partitions are deformable; they could also consist of a partition that has a piston represents and includes a column of liquid.

In another embodiment, not shown, to increase the capabilities of the engine, increase the mass displaced in each circuit; to this end, the two can Pistons are connected to a piston rod, which may be loaded with a mass.

5 As FIG. 5 shows, there is a further embodiment of the Invention of two chambers 33, 34, each of which contains a deformable pocket 35, which is filled with a thermodynamic medium is filled.

As before, the chambers 33, 3 4 are interconnected by a channel 3 6 connected. The volume thus delimited contains a relative to the operating temperatures of the system inert liquid, i.e. a liquid that does not evaporate at the temperature of the heat source.

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The evaporation of the thermodynamic medium in the chamber 33 on the side of the heat source causes the displacement of the medium against the chamber 34 on the side of the cold source and thus generates a drive torque.

To improve the functioning, it is advantageous to close the chambers of the various subgroups against one another isolate.

The inlets and outlets for the heat exchange medium of the heat source and the cold source have the reference numerals 37, 38; 39, 40.

Figures 6 and 7 show two examples of tunnels for the heat source and the cold source. On the side facing the center of the ring area, the tunnels have a passage 41 for channels 32, 36.

In order to prevent the partition 27 or the pocket 35 from closing the channels 32, 36, these are provided with a protective device 42 provided (Fig. 5).

It should be pointed out that the rotor 21 of FIG. 5 also applies to the case of one formed directly by the solar radiation Heat source is applicable. In this case, the tunnel of the stator 20 is omitted at least in the part that the Represents a source of heat or is replaced by a tunnel with a greenhouse effect.

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Claims (1)

PATENT CLAIMS 10 15th Rotating fluid motor for a thermodynamic Medium, with a group of common rotating units, each of which consists of two diametrically opposed rigid subsets of constant volume that contain a thermodynamic medium that alternates evaporates and condenses, depending on whether the corresponding subgroup is exposed to a heat source or exposed to a source of cold, characterized in that each subset of a deformable seal Chamber (6, 28, 30, 35) consists of a thermodynamic medium and a heavy transmission device (4, 32, 36) which immediately and completely record any change in volume of one of the chambers (6, 28, 30, 35) the other chamber transmits, the transmission device thus assuming a position of disturbed equilibrium and generates a torque which is transmitted to the shaft (7) of the motor. 20th Engine according to Claim 1, characterized in that the transmission device consists of a unit of two pistons consists, which are firmly connected to each other for common movement, and that each piston is the movable wall each forms a deformable chamber. COPY 3. Motor according to claim 1, characterized in that the The transmission device consists of a column of liquid (4) that is resistant to the temperatures and operating conditions of the engine is sluggish and is enclosed between two pistons (5, 27, 35), which form the tight chambers with variable volumes, each of which contains a thermodynamic medium. 4. Motor according to claim 3, characterized in that the ■ Pistons are formed by elastically deformable partitions (27) or pockets (5, 35). 5. Motor according to one of claims 1 - 4, characterized in that that it contains a stator (20) and a rotor (21), the stator (20) having the shape of a tunnel, which is surrounded by a shell (23) in which the heat exchange medium of the heat source or the cold source flows, and which in turn is surrounded by an insulating sleeve (22), and wherein the rotor (21) consists of various rotating units is composed, which are formed by sub-groups, with the rotor in the delimited by the stator (22) Space circulates. 6. Motor according to claim 5, characterized in that the part of the stator (20) which corresponds to the heat source, consists of a chamber that creates a greenhouse effect, with the outer insulating cover being omitted. 7. Motor according to claim 6, characterized in that the successive chambers of the various subgroups are thermally isolated from one another. Copy