DE102015225726A1 - Pump with deformable conveying element - Google Patents

Abstract

The invention relates to a pump with a conveying element (1) for the inflow and outflow of a medium. The conveying element (1) communicates with a drive (2). The drive (2) has a material (5) for performing a thermal change of its geometric dimensions. The drive communicates with the conveying element (1) for changing the shape. The change in shape causes a promotion of the medium.

Description

The invention relates to a pump with a conveying element for the inflow and outflow of a medium, wherein the conveying element is in communication with a drive, and a method for conveying a medium.

Pumps are working machines used to convey media. In addition to liquids include, among others, liquid-solid mixtures, pastes or liquids with a gas content to these media. For this, the medium is set in motion via a drive.

Pumps are subdivided according to their functional principle. The invention relates to a positive displacement pump. A delivery element sucks the medium in a first phase of a cycle and pushes the medium out in a next phase.

In diaphragm pumps, the conveying element is designed as a membrane, which are in communication with a drive. The drive is often a piston used, which performs oscillating movements. The movement of the piston causes a rash of the membrane, thereby causing suction and pressure pulses.

In the EP 1 813 803 A1 a fuel pump for an internal combustion engine will be described. The fuel pump includes a pumping chamber having an inlet valve and an outlet valve. The pumping chamber is closed on one side by a flexible membrane. An actuator acts on the diaphragm to vary the volume of the pumping chamber cyclically. The actuator includes a shape memory material coupled to the flexible membrane.

The object of the invention is to provide a pump that can operate largely independently of conventional energy sources. Furthermore, a method for conveying a medium is to be specified, which can be operated without a complex infrastructure or without a long supply line. Also, the pump should be characterized by a long life, a reliable operation and the lowest possible acquisition or operating costs.

This object is achieved by a pump having the features of claim 1 and a method having the features of claim 13. Preferred variants can be found in the subclaims, the description and the drawing.

According to the invention, the drive has a material for performing a thermal change of its geometric dimension. By heat development, the material expands or contracts. Due to the thermal expansion or heat shrinkage changes the length, the surface area or the volume of the body, which is made of this material.

According to the invention, the material is connected to the conveying element of the pump in such a way that the changes in the geometric dimensions of the material cause a change in shape of the conveying element. This change in shape of the conveying element leads to the promotion of the medium.

In a particularly favorable variant of the invention, the material is a shape memory alloy. Shape memory alloys (abbreviation: SMA) are special metals that can exist in two different crystal structures. They are often referred to as memory metals.

This is due to the phenomenon that they seem to be reminiscent of an earlier shaping despite subsequent severe deformation.

Preferably, a nickel-titanium alloy is used as the material. These are characterized by particularly large effects combined with high strength. When the temperature changes, a phase transition takes place.

In a particularly favorable variant of the invention, the drive also has a material for oxidation. Preferably, this is a catalytic material, wherein in particular a platinum-containing material is suitable. In one variant of the invention, nanoparticles of platinum are used. These are applied in a particularly preferred embodiment of the invention on tiny tubes made of carbon.

The material comes into contact with at least one substance which is reacted with oxygen in a catalytic reaction. The substances may be, for example, hydrogen or organic compounds such as methanol. In one variant of the invention, organic compounds which are dissolved in the water are used as substances. These may be, for example, sugars or carbohydrates such as starch. Polluted waters, in particular, often have a large number of organic substances which are suitable as substances for oxidative conversion.

The exothermic oxidative reaction releases heat which is transferred to the material to effect a thermal change. Due to the temperature increase change the geometric dimensions and there is a change in length, area or volume, which lead to a change in shape of the conveying element.

In a particularly favorable variant of the invention, the material responsible for the oxidation is arranged around the material, which performs a thermal change of the geometric dimension. For example, the material for thermal modification may be rod-like, preferably in the form of a cylinder. The catalyst material is then arranged around this rod-like body, this preferably forming a hollow-cylindrical body. On the outer annular catalyst shell exotherms the oxidation reaction and transfers the heat to the inner core, which performs a change in length due to the temperature rise.

In a particularly advantageous variant of the invention, the conveying element consists at least partially of an elastic material. Preferably, a rubber-elastic material is suitable. For example, the conveying element may consist of a silicone rubber or a silicone elastomer. Thus, the conveying element is elastically deformable and can lean against the housing walls of the pump if necessary.

In a particularly favorable embodiment of the invention, the conveying element has a crescent-shaped cross section. The conveying element is preferably designed as a bell-shaped body.

In an advantageous variant of the invention, the conveying element is in operative connection with the drive via a connecting element. By way of example, the connecting element may be a wire which is attached to the conveying element and, in the event of a contraction of a material of the drive, deforms the conveying element in one direction, so that medium is conveyed. In a particularly favorable variant, the connecting element is at least partially arranged in the conveying element. Thus, a trained as a wire connecting element in the elastic mass, of which the conveying element consists, be embedded.

In a particularly favorable embodiment of the invention, the pump has a return element, which deforms the conveying element after a deformation of the conveying element by the drive.

During a first phase, there is a thermal change of a material of the drive, which leads to a change in shape of the conveying element, which is sucked by this change in shape, for example, medium. In a second phase, the return element ensures that the conveying element returns to its original position. By this shape change back to the initial state, for example, medium is pushed out.

The phases described above repeat themselves cyclically.

The restoring element can be, for example, a spring element which acts as a return spring, in particular a leaf spring element.

In a variant of the invention, the return element is integrated in the conveying element. For example, a return spring may be embedded in the conveyor element made of an elastic mass.

Preferably, the drive is fixed in place at one end. At the other end of the drive is connected via a connecting element with the conveying element in connection. As a result of the contraction and expansion processes in the drive, this results in a deformation movement of the conveying element, which leads to a delivery of the medium.

It proves to be particularly favorable when the drive is arranged in a space which is closed with respect to the medium to be conveyed.

The space has an inlet through which the educts for the oxidation flow to the catalyst material. The material undergoes catalytic oxidation. This may be a total oxidation with the products water or carbon dioxide or a partial oxidation in which carbon monoxide or organic products may also be formed.

A stream of the resulting products and the unreacted educts leaves the room through an outlet.

Further features and advantages of the invention will become apparent from a description of an embodiment with reference to a drawing and the drawing itself.

It shows

1 a schematic representation of the invention,

2a an arrangement of a pump in a pipe in a ground state,

2 B an arrangement of a pump in a pipe during suction,

2c an arrangement of a pump in a pipe during ejection.

The 1 shows a pump for delivering a medium, which flows according to the left block arrow in the pump and flows out of the pump according to the right block arrow.

The pump comprises a conveying element 1 , The conveying element 1 is executed in the embodiment as a bell-shaped silicone shell and has a crescent-shaped cross-section.

The conveying element 1 is with a drive via a connecting element 3 connected. At the connecting element 3 in the exemplary embodiment, this is a wire that is in the conveying element 1 is embedded and by means of pulleys 4 connected to the drive.

The drive comprises a first material 5 , which is formed as an inner core in the form of a cylinder and a second material 6 as outer shell, the annular ring the first material 5 surrounds.

In the rod-like core of the drive 2 it is a material 5 for performing a thermal change of the geometric dimensions. In the exemplary embodiment, a shape memory material is used, which is designed as a nickel-titanium alloy.

The annular outer shell of the drive 2 consists of a material 6 which serves as a catalyst for an oxidation reaction. In the exemplary embodiment, a platinum-containing material is used. These are carbon nanotubes coated with platinum particles.

Through an inlet 7 flows according to the upper block arrow, a mixture in a room 8th containing an oxidizing agent and a substance to be oxidized. In the exemplary embodiment, the oxidant is oxygen or air and the substance to be oxidized is hydrogen.

The space 8th is from a housing 9 from the room 10 separated, in which the medium to be conveyed is located.

The oxidizing agent becomes with the oxidizing agent on the catalytic material 6 implemented. In the exemplary embodiment, hydrogen and oxygen react to form water. The mixture with the reaction products and the unreacted starting materials leaves the room 8th through an outlet 14 in the direction of the lower block arrow.

In the exothermic reaction heat is released, which is transmitted to the inner core of the drive branch. The material 5 heats up and changes its geometric dimensions. For example, there may be a length contraction, so that the rod-like drive 2 contracts.

This will be the wire-like connection element 3 stretched so that the flanks of the bell-shaped conveying element 1 be deformed upwards. The position is shown as a dashed line in the figure.

The ends of the conveyor element 1 lie close to the walls 11 a housing of the pump.

In the deformation of the conveying element 1 upward is medium through the supply line 12 in by deformation of the conveying element 1 enlarged space 10 sucked. A first backflow prevention element 13 opens.

In a second phase, the oxidation reaction on the material ends 6 , The reaction comes to a standstill, for example, because no new oxidizing agent is supplied more or in space 8th was already consumed. Without the exothermic reaction, the rod-like drive cools 2 from. For example, this leads to a change in length, whereby the wire-like connecting element 3 its mechanical tension loses and the flanks or wings of the bell-shaped conveying element 1 again fold down into the starting position shown as a solid line.

This will make the room 10 downsized and the medium is through a derivative 14 promoted beyond. This opens a second backflow prevention element 15 that was closed during the previous intake process. During the now proceeding expression process is the first backflow prevention element 13 closed.

A reset element 17 , which is designed in the embodiment as a return spring, brings the conveying element 1 back to its starting position.

The phases described above repeat themselves cyclically.

2a shows an arrangement of a pump in a pipe with a conveying element 1 in the embodiment according to the 2a . 2 B and 2c , designed as a flexible pipe wall.

The arrangement comprises a holder 19 , The holder 19 is stationary and therefore forms a fixed point for a relative movement of the drive 2 , Via a connecting element 3 , which is executed in the embodiment as a wire, is the drive 2 with the conveying element 1 in connection. The connecting element 3 is via pulleys 4 guided and attacks at one point 20 of the conveyor element 1 ,

The arrangement has a first backflow prevention element 13 and a second backflow prevention element 16 , These are at the entrance or exit of the room 10 arranged.

2 B shows a suction process of the arrangement. The drive 2 is in a stretched state. The trained as a flexible pipe wall conveyor element 1 it is arched outwards. By the first backflow prevention element 13 medium flows into a room 10 while the second backflow prevention element 16 the room 10 closes.

2c shows an ejection operation of the arrangement. The drive 2 is in a contracted state and pulls the designed as a flexible pipe wall promotion element 1 inside. This will make the medium out of the room 10 displaces and flows over the now open backflow prevention element 16 from.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1813803 A1 [0005]

Claims (15)

Pump with a conveying element ( 1 ) for the inflow and outflow of a medium, wherein the conveying element ( 1 ) with a drive ( 2 ), characterized in that the drive ( 2 ) a material ( 5 ) for carrying out a thermal change of the geometric dimensions associated with the conveying element ( 1 ) is in communication with the change in shape, wherein the change in shape causes a promotion of the medium. Pump according to claim 1, characterized in that the material ( 5 ) is a shape memory alloy, in particular a nickel-titanium alloy acts. Pump according to claim 1 or 2, characterized in that the drive ( 2 ) a material ( 6 ) for oxidation, which is used to transfer heat with the material ( 5 ) for performing the thermal change of the geometrical dimensions. Pump according to one of claims 1 to 3, characterized in that the material ( 6 ) for oxidation around the material ( 5 ) is arranged for the thermal change of the geometric dimensions. Pump according to one of claims 1 to 4, characterized in that the drive ( 2 ) a rod-like core of the material ( 5 ) for performing a thermal change in length, around which the material is arranged for oxidation. Pump according to one of claims 1 to 5, characterized in that the conveying element ( 1 ) consists at least partially of an elastic material, in particular a rubber-elastic material. Pump according to one of claims 1 to 6, characterized in that the conveying element ( 1 ) has a crescent-shaped cross-section, wherein the conveying element is preferably formed as a bell-shaped body. Pump according to one of claims 1 to 7, characterized in that the drive ( 2 ) is fixed at one end, wherein preferably the other end via a connecting element ( 3 ) with the conveying element ( 1 ). Pump according to one of claims 1 to 8, characterized in that the conveying element ( 1 ) via a connecting element ( 3 ) with the drive ( 2 ) is in operative connection, which is preferably formed like a wire. Pump according to one of claims 1 to 9, characterized in that the pump is a restoring element ( 17 ) for changing the shape of the conveying element ( 1 ) having. Pump according to one of claims 1 to 10, characterized in that the drive ( 2 ) in a room ( 8th ) having an inlet ( 7 ) for educts for oxidation, wherein the space ( 8th ) is preferably completed with respect to the medium to be delivered. Pump according to one of claims 1 to 11, characterized in that the drive ( 2 ) in a room ( 8th ) having an outlet ( 14 ) for products of oxidation and unreacted starting materials. Method of conveying a medium with the following steps: - oxidation on a material ( 6 ), - generation of heat by oxidation, - transfer of heat to a material ( 5 ), - thermal change in length of the material ( 5 ), - deforming a conveying element ( 1 ), - generation of a flow of the medium, - cooling of the material ( 5 ), - thermal change in length of the material ( 5 ), - deformation of the conveying element ( 1 ), - generating a flow of the medium Method according to claim 13, characterized in that the material ( 5 ) contraction when heated. Method according to claim 13 or 14, characterized in that the material ( 5 ) performs an expansion on cooling.

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