DE10209998B4 - Gas expansion element for an arrangement for converting thermal into motor energy - Google Patents

Abstract

Gas expansion element for an arrangement for converting thermal into motor energy, in particular for a hot water engine, consisting of a closed pressure container (1) filled with a gas or gas mixture, which is effectively connected to the arrangement via a liquid piston (4) and each has an upper injection opening (2, 3) for hot water and for cold water and a lower water drain opening (12) connected to a working circuit (14), characterized in that the liquid piston (4) is provided inside the pressure container (1).

Description

The invention relates to a Gas expansion element for an arrangement for converting thermal into motor energy, especially for a hot water engine consisting of one with a gas or gas mixture filled closed pressure vessel, the over a liquid piston is effectively connected to the arrangement and each has an upper injection opening for hot water and for cold water and has a lower water drain opening connected to a working circuit.

From the EP 0 043 879 A1 is a gas expansion element designed as a cylinder for an arrangement for converting thermal into motor energy. A piston with a piston rod is slidably mounted in the cylinder. The cylinder chamber which is penetrated by the piston rod has an inlet valve and an outlet valve for air, the outlet valve being coupled to a working chamber of the cylinder via a bypass. The work area is equipped with an injection opening for hot water and an outlet valve. With the bearing of the piston and piston rod in the cylinder, there are relatively large friction losses.

WO 00/53898 also discloses a gas expansion element for an arrangement for converting thermal into motor energy, in particular for one Hot water engine consisting of one with a gas or gas mixture filled closed pressure vessel. The pressure vessel is over a slidable piston effectively connected to the arrangement and each has an upper injection opening for hot water and for cold water and a lower water drain opening. The piston is a liquid piston pump trained, the input side with the water drain opening of the Pressure vessel, which is assigned a water inlet of a working circuit, and connected on the output side to a water drain of the working circuit is.

Furthermore, the DE 27 43 584 A1 a heat engine with a condensable vapor as the working fluid, in which the heat supply to the working fluid in a zone having the dead volume of the cylinder of the machine, the working fluid being introduced as a pure liquid mist into the displacement of the cylinder. Furthermore, the US 4,220,005 a combination of a generator and a motor unit, wherein the generator works with an evaporated working fluid and the generator is coupled in communication with the motor. The working fluid is injected into an externally heated housing with heat-conducting elements in a synchronized relationship with the cyclical operation of the engine. After all, is out of US 3 862 590 A1 a displacement motor is known in which water is injected into an injection chamber of a cylinder head.

It is an object of the invention To create gas expansion element of the type mentioned, the has a relatively high efficiency with a simple structure.

According to the invention the object is achieved in that the liquid piston inside the pressure vessel is provided.

Due to the arrangement of the liquid piston inside the pressure vessel it is not necessary to add an additional component, for example a separate liquid piston pump, for transmission the expansion energy of the compressible gas or gas mixture to a non-compressible medium and its resetting provided. About that In addition, energy losses due to transmission paths are avoided. That contracting with the supply of cold water and with the supply of Hot water expanding gas, such as air, is applied directly the liquid piston or is from the liquid piston pressurized, who does the work that goes into the work cycle Conversion of thermal energy is supplied.

Preferably floats on the pressurized surface of the liquid piston a pressure-resistant separating layer acted upon by the gas or gas mixture. The separation layer essentially defines that of the gas or The gas mixture directly acts on the surface of the liquid piston and ensures even power transmission.

The separating layer is expedient to the inner wall of the pressure vessel slightly spaced. The spacing of the separating layer ensures that that into the pressure vessel sprayed Hot or cold water over the water drain opening is derived, which is why the liquid piston in a starting position not acted upon by the gas a constant Level and the pressure vessel completely above the separation layer filled with the gas or gas mixture is.

According to an advantageous embodiment the invention is the release layer as a pressure-resistant outer skin and a cone comprising a float core. The cone favored a swirling of the warm sprayed into the pressure vessel or cold water with the gas, so that rapid heating or cooling down of the gas.

In order to achieve a relatively stable structure of the cone with a relatively thin design of the outer skin, the outer skin is preferably supported directly on the float core. The float core thus stabilizes the outside skin of the cone.

For quick derivation of the in the pressure vessel sprayed The outer skin is expediently cold or hot water made from a water-repellent and heat-resistant material. About that also protects the heat-resistant material the outer skin the float body from temperature-related damage. Preferably there is the outer skin made of stainless steel, a titanium or aluminum alloy.

So that a thermal separation between the sprayed Cold or hot water and the liquid piston is largely ensured, there is advantageously the floating core made of a polyvinyl chloride or rigid polyurethane foam.

To drain the sprayed cold or To favor hot water from the cone and a relatively large one lifting surface available to is preferably the tip of the cone towards the top Injection ports aligned.

So that the cone experiences a relatively large buoyancy, points the cone one on the surface of the liquid piston floating cylindrical approach whose outer diameter is the largest diameter of the cone.

After a further development of the inventive idea is the Ke gel a guide assigned to the centering of the cone within the pressure vessel. Thus, the cone always has a defined position within the pressure vessel and lateral tipping of the cone is impossible.

The guide device preferably comprises a guide rod attached to the cone, the in one in the pressure vessel arranged guide sleeve slidable is stored. The leadership facility is therefore complete inside the pressure vessel arranged.

In a further embodiment of the invention is the leader a measuring system assigned. The position of the Cone and thus always the position of the liquid piston within the pressure vessel to determine exactly. After coupling the measuring system with an appropriate control of the injection nozzles an injection of cold or hot water depending on the position of the liquid piston. The measuring system is designed, for example, as an inductive displacement transducer and sends one electrical signal to the control unit, the actuators for opening and Conclude controlled by valves.

It is understood that the above not only mentioned features and to be explained below in the specified combination, but also in others Combinations can be used without the scope of the present Leaving invention.

The invention is explained below of an execution example with reference to the related Drawing closer explained. The only FIG. Shows a schematic representation of a gas expansion element according to the invention with assigned components.

A cylindrical pressure vessel 1 has an injection opening on its top 3 for cold water and an injection opening 2 for hot water, with both injection openings 2 . 3 each with a spray and atomizer nozzle directed into the interior 21 are provided. Inside the closed pressure vessel 1 there is a liquid piston 4 from water, on its surface 5 a separation layer 6 swims. The interface 6 includes a cone 7 whose apex enclosing an obtuse angle 8th towards the injectors 2 . 3 points, and one at the bottom of the cone 7 arranged cylindrical approach 9 , The diameter of the approach 9 corresponds to the largest diameter of the cone 7 , al– so that of the base of the cone 7 , The interface 6 consists of an outer skin made of a pressure and heat resistant material 10 as well as the outer skin 10 supporting float body 11 , The diameter of the approach 9 and thus also the diameter of the base of the cone 7 has a slight clearance to the inner wall of the pressure vessel 1 on. In the ground 22 of the pressure vessel 1 is a water drainage opening 12 let in through lines 23 with check valves inserted 13 with a working cycle 14 communicates.

At the top 8th of the cone 7 is a guide rod 15 attached to the centering of the interface 6 in the pressure vessel 1 with one on the top of the pressure vessel 1 fixed guide sleeve 16 interacts. The guide rod also works 15 and the guide sleeve 16 as an inductive measuring system 24 together, which is an electrical signal regarding the position of the cone 7 and therefore the height of the surface 5 of the liquid piston 4 to a control unit 17 sends.

Circulating air 18 or other gases or gas mixtures within the pressure vessel 1 To heat, warm water is injected through the injection port 2 inside the pressure vessel 1 sprayed. To do this, the control unit opens 17 one of the injection port 2 assigned, in a supply line 25 inserted valve 19 by being an actuator 26 of the valve 19 via a connecting line 27 controls. When the warm water is sprayed in, the air expands 18 and performs on the sliding liquid piston 4 Job. The change in distance of the liquid piston 4 is from the measuring system 24 detects a corresponding electrical signal for evaluation via the line 28 to the control unit 17 transmitted. The temperature distribution of the warm water within the air 18 is due to the shape of the cone 4 favored. After the liquid piston 4 has reached a lower end position, the injection zöffnung 2 for the hot water by controlling the actuator accordingly 26 of the valve 19 through the controller 17 closed. One of the check valves 13 is opened and the pressure generated is planted in the working cycle 14 continued. During this time, the other is the check valve 13 closed that when contracting the air 18 in the pressure vessel 1 is opened.

After the pressure rises and the pressure drop in the pressure vessel caused by the liquid piston dis- placement as well as after a corresponding reduction in temperature, water falls out through the outer skin 10 of the cone 7 the liquid piston 4 and about this the working cycle 14 is fed.

To contract the air 18 is over the with the spray and atomizer nozzle 21 provided injection opening 3 Cold water in the pressure tank 1 sprayed by one into a lead 25 inserted valve 20 by acting on an actuator 26 on the part of the control unit 17 is opened. The liquid piston comes through the resulting negative pressure 4 in its upper end position, which is also due to the position measuring system 24 is recorded. When the upper end position is reached, the measuring system sends over a line 28 an electrical signal for further processing to the control unit 17 , which then the actuator 26 of the valve 20 causes it to close.

Claims (13)

Gas expansion element for an arrangement for converting thermal into motor energy, in particular for a hot water motor, consisting of a closed pressure vessel filled with a gas or gas mixture ( 1 ) using a liquid piston ( 4 ) is effectively connected to the arrangement and each has an upper injection opening ( 2 . 3 ) for hot water as well as for cold water and a lower one with a working circuit ( 14 ) connected water drain opening ( 12 ), characterized in that the liquid piston ( 4 ) inside the pressure vessel ( 1 ) is provided. Gas expansion element according to claim 1, characterized in that on the pressurized surface ( 5 ) of the liquid piston ( 4 ) a pressure-resistant separating layer acted upon by the gas or gas mixture ( 6 ) swims. Gas expansion element according to claim 2, characterized in that the separating layer ( 6 ) to the inner wall of the pressure vessel ( 1 ) is slightly spaced. Gas expansion element according to claim 2 or 3, characterized in that the separating layer ( 6 ) as a pressure-resistant outer skin ( 10 ) and a float core ( 11 ) comprehensive cone ( 7 ) is trained. Gas expansion element according to claim 4, characterized in that the outer skin ( 10 ) directly on the float core ( 11 ) supports. Gas expansion element according to claim 4 or 5, characterized in that the outer skin ( 11 ) is made of a water-repellent and heat-resistant material. Gas expansion element according to one of claims 4 to 6, characterized in that the outer skin ( 11 ) consists of a stainless steel, a titanium or aluminum alloy. Gas expansion element according to claim 4 or 5, characterized in that the float core ( 11 ) consists of a polyvinyl chloride or rigid polyurethane foam. Gas expansion element according to claim 4, characterized in that the tip ( 8th ) of the cone ( 7 ) in the direction of the upper injection openings ( 2 . 3 ) is aligned. Gas expansion element according to claim 9, characterized in that the cone ( 7 ) one on the surface ( 5 ) of the liquid piston ( 4 ) floating cylindrical approach ( 9 ) whose outer diameter is the largest diameter of the cone ( 7 ) corresponds. Gas expansion element according to claim 4, characterized in that the cone ( 7 ) a guide device for centering the cone in position ( 7 ) inside the pressure vessel ( 1 ) assigned. Gas expansion element according to claim 10, characterized in that the guide device on the cone ( 7 ) attached guide rod ( 15 ) which is contained in a pressure vessel ( 1 ) arranged guide sleeve ( 16 ) is slidably mounted. Gas expansion element according to claim 11 or 12, characterized in that the guide device has a displacement measuring system ( 24 ) assigned.