JP2009532616A - Piston pump for concentrated material - Google Patents

Abstract

The invention relates to a piston pump for thick matter, in particular for high-solids sewage sludge, coal sludge and concrete. The piston pump has at least one delivery cylinder (16) which contains a motor-driven or hydraulically driven delivery piston (20) and which has an orifice (12) which communicates alternately with the interior of a material feed container (10) and with a pressure delivery line (30) in a slide-controlled manner in accordance with the movement of the delivery piston (20). In order to significantly increase the degree of filling of the at least one delivery cylinder (16), an annular nozzle (32) opening into the delivery cylinder (16) in the region of the orifice (12) is provided, and this annular nozzle (32) is connected to an external pressure line (34) to which a lubricant can be admitted.

Description

  The present invention relates to a piston pump for dense substances (high viscosity substances) having at least one supply cylinder comprising a motor-driven or hydraulically driven supply piston. The supply cylinder has an orifice opening communicating alternately with the inside of the material filling container and the pressure supply line. The orifice opening is slide-controlled according to the movement of the supply piston.

  This type of piston pump is used for conveying solid-liquid mixtures with a high proportion of solids such as, for example, sewage sludge, coal slurry, biomass or concrete. Such concentrated materials have large internal friction, so that the filling degree of the supply cylinder frequently leaves what is desired during the suction stroke. On the other hand, in the case of this kind of piston pump, it is known to introduce a lubricant between the concentrated material strand and the pressure supply line wall in order to reduce wall friction at the position of the pressure supply line (patent) Reference 1). This is usually done continuously and in a metered quantity proportional to the feed flow, resulting in the formation of a boundary layer between the inner wall of the pipe and the dense material strand. With the boundary layer, the supply pressure can be reduced. As the lubricant layer gradually disappears along the supply section, additional lubricant must be injected into the pressure supply line at some interval. In order to increase the filling degree of the supply cylinder, a preloading device (prepressing device) is usually provided in the region of the material filling container. Using the preload device, the filling pressure can be increased to at least 1 bar. In many cases, however, this is not sufficient.

EP-B-633863

  The object of the present invention is based on the improvement of a known piston pump for concentrated substances so that the filling degree in the supply cylinder can be significantly increased even when the proportion of solids in the concentrated substance is high.

In order to solve the above-mentioned problem, a combination of feature configurations mentioned in claim 1 is proposed. Advantageous embodiments and further developments of the invention are evident from the dependent claims.
The solution according to the invention is mainly based on the idea that a ring nozzle opening into the supply cylinder is arranged in the region of the orifice opening, said ring nozzle being connected to an external pressure line, thereby The pressure line can fill the ring nozzle with lubricant through a high-pressure pump. It is advantageous if the pressure line is connected to a ring flow path which opens to the ring nozzle via a hole arranged in the orifice area of the supply cylinder.

  In a preferred structural embodiment of the invention, the supply cylinder carries an outer ring having at least one hole connected to the pressure line on the outside, and has a ring flow path to the ring nozzle, whereby the ring flow. The path is bounded on the inside by the outer surface of the supply cylinder or on the outer surface of the inner ring following it in the axial direction and on the outside by the inner surface of the outer ring. It is useful if the inner ring described above engages a recess in the outer ring that opens inward and defines a ring nozzle and ring flow path with this ring. In this connection, it is advantageous if an inner ring with a radially projecting rear neck is sandwiched and supported between two ring surfaces of the supply cylinder and the outer ring body facing each other.

  It is useful for the ring channel to have at least one ring-shaped cross-sectional extension in order to ensure a uniform distribution of the concentrated material over the periphery. It is advantageous if there are two ring-shaped cross-section extensions that are spaced apart from one another.

  According to a preferred embodiment of the present invention, the supply cylinder is provided with a control device that responds to the position and / or stroke direction of the supply piston, and a control valve arranged in the pressure line in response to an output signal of the control device. Yes. The control valve opens during the suction stroke (process) of the supply piston and closes before the pressing stroke. In this connection, it is useful if the control valve is shaped like a directional valve that is preferably magnetically controllable via a supply piston.

  In a preferred embodiment of the invention, two supply cylinders, each having a ring nozzle in its orifice area, are provided, each ring nozzle having a suction stroke of each of the supply pistons controlled in a push-pull or reverse cycle. Meanwhile, the lubricant can be filled through the control valve.

  The invention further relates to a method for driving a piston pump for concentrated material. In that case, the concentrate material is alternately drawn into the supply cylinder which is open on one side during the suction stroke and exits the supply cylinder and is pushed into the pressure supply line during the subsequent pressing stroke. In order to significantly increase the filling degree of the supply cylinder, it is proposed according to the invention to inject lubricant into the supply cylinder at each suction stroke. In this connection, it is advantageous if the lubricant is injected into the separation region between the concentrate material and the inner surface of the supply cylinder. Among them, it is advantageous to inject all around. In order to avoid unintentional emptying of the pull-in line for the lubricant, it is useful if the lubricant injection is interrupted during the pressing stroke. The lubricant is injected at a pressure higher than the pressure of the concentrated material disposed in the supply cylinder. It is useful if the injection pressure is greater than 50 bar, in particular about 100 bar, while it is useful if the pre-pressing pressure on the concentrate material during the suction stroke is approximately 2 bar.

  The preferred embodiments of the present invention assume the following. That is, in the case of a two-cylinder type piston pump, the pistons in the first and second supply cylinders are driven while performing the suction stroke and the pressing stroke by the push-pull method, and at that time, lubricating oil is supplied during each suction stroke. It is injected into the cylinder and the injection of lubricant is interrupted during each pressing stroke.

  With the measures according to the invention, a marked improvement in the filling degree (filling degree) in the supply cylinder is achieved, in particular in the case of concentrated substances with a high solid content. In addition, the lubricant film (lubricant layer) generated in the supply cylinder is taken into the pressure supply line, so that no additional lubricant injection is required anymore in the first line part following the concentrate pump. Only in the case of a long pressure supply line having a length of 50-100 m or more, additional lubricant can be injected into the pressure supply line away from the concentrate pump. Lubricant is injected into the supply cylinder only during the suction stroke, while lubricant injection into the pressure supply line must be performed continuously.

In the following, the present invention will be described in more detail using exemplary embodiments schematically illustrated in the drawings.
The two-cylinder rich material pump schematically shown in FIG. 1 is intended to carry rich materials that are rich in solids such as partially dewatered sewage treatment sludge, coal dust sludge, or concrete. ing.

  The piston pump basically includes a material filling container 10, two supply cylinders 16, two supply pistons 20, and a water chamber (cooling can) 22. The two supply cylinders are connected to the material filling container 10 through an orifice opening 12 and a wall opening 14 on the supply cylinder end side. The two supply pistons can be driven via a hydraulic drive cylinder 18 in a push-pull manner (reverse cycle). The water chamber is disposed between the drive cylinder 18 and the supply cylinder 16. A pipe slide 24 is arranged inside the material filling container 10, and the pipe slide can be alternately connected to the orifice opening 12 of the supply cylinder where the piston performs the pressing stroke at the inlet opening 26. The piston opens the orifice opening 12 of the other supply cylinder that performs the suction stroke, and the outlet opening 28 is connected to a pressure supply line (not shown) via a pressure connector 30 arranged in the material filling container 10. Connected. In the case of the embodiment shown in FIG. 1, the pipe slide 24 has a swivel pipe that can be swiveled in the material filling container 10 and bent into an S shape. Correspondingly, the concentrated material reaches from the inside of the material-filled container 10 during the respective suction stroke, possibly under the action of preload pressure, into the associated supply cylinder 16 via the open orifice opening 12. . On the other hand, the concentrated substance in the other supply cylinder 16 is pushed into the next pressure supply pipe by the supply piston 20 performing a pressing stroke via the turning pipe of the pipe slide 24 and the pressure connector 30.

  A unique feature of the present invention is that a ring nozzle 32 is disposed in the region of the orifice opening 12, and the ring nozzle passes through the pressure pipe 34, the hole 36, and the ring flow path 38, and supplies the lubricant at a pressure of about 50 to 100 bar. The point is that it can be applied. An inner pipe 40 continues in the axial direction to the supply cylinder 16 in the region of the orifice opening 12 in order to form the ring channel 38 and the ring nozzle 32. The inner pipe is covered with an outer pipe 42 screwed into the supply cylinder 16. For this purpose, the inner ring 40 has a radially projecting neck (collar) 44. The neck is attached between the ring surface 46 of the outer pipe 42 and the end side ring surface 48 of the supply cylinder 16 to ensure that the ring nozzle 32 and the ring flow path 38 are open between the inner pipe and the outer pipe. ing. A hole 36 for supplying the lubricant is arranged in the outer pipe 42. The inner pipe 40 has two ring grooves on its inner surface that define the boundary of the ring flow path. The groove forms a cross-sectional extension 50 and ensures that the lubricant flowing out of the ring nozzle 32 is evenly distributed over the periphery.

  In order to supply the lubricant to the individual supply cylinders 16, an external control device (not shown) is controlled so that the lubricant is injected into the supply cylinders only during the suction stroke. The lubricant then enters the separation region between the dense substance and the inner surface of the supply cylinder, so that the degree of filling is improved for reducing sliding friction. Experiments have shown that with the measures according to the invention, it is possible to achieve an improvement in the filling degree of at least 25% in the case of sewage sludge rich in solids. During the subsequent pressing stroke, the lubricant reaches the pressure line with the concentrated material, where it also reduces sliding friction. During the pressing stroke, the injection of lubricant is interrupted each time. In this way, the risk of lubricant-induced empty suction due to the dense material flowing through is avoided.

  In summary, the following is confirmed: The present invention relates to piston pumps for dense materials, in particular for solids-rich sewage sludge, coal slurries and concrete. The piston pump has at least one supply cylinder 16 including a motor-driven or hydraulically driven supply piston 20. The cylinder has an orifice opening 12 which is slide-controlled according to the movement of the supply piston 20 and communicates alternately with the inside of the material filling container 10 and the pressure supply line 30. In order to significantly increase the degree of filling of the at least one supply cylinder 16, a ring nozzle 32 that opens into the supply cylinder 16 is provided in the region of the orifice opening 12. The ring nozzle is connected to an external pressure line 34 to which a lubricant is supplied.

It is a top view of the 2 cylinder piston pump for rich substances for connecting to a supply line. FIG. 2 is a plan view of the two-cylinder piston pump according to FIG. 1 shown in enlarged depiction without a material filling container. It is sectional drawing of the 2 cylinder piston pump which concerns on FIG. 2b is an enlarged detail view of the cross-sectional view according to FIG. 2b. FIG. 4 is a cross-sectional view through one orifice region of a supply cylinder, enlarged as compared to FIG. 3.

Explanation of symbols

10 Material Filling Container 12 Orifice Opening 16 Supply Cylinder 20 Supply Piston 30 Pressure Connector 32 Ring Nozzle 34 Pressure Line

Claims (18)

  The concentrated material piston pump has at least one supply cylinder (16) including a motor-driven or hydraulically-driven supply piston, the supply cylinder being connected to the interior of the material-filled container (10) and the pressure supply line (pressure connector 30). In the rich piston pump, the orifice opening (12) alternately communicating with the supply piston (20) is controlled in accordance with the movement of the supply piston (20). A piston pump characterized in that a ring nozzle (32) opens into the supply cylinder (16) in the region 12), and the ring nozzle is connected to at least one external pressure line (34).   Piston pump according to claim 1, characterized in that the pressure line (34) can be filled with a lubricant by means of a high-pressure pump.   The pressure line (34) is connected to a ring flow path (38) opened to the ring nozzle (32) through a hole (36) disposed in an orifice region of the supply cylinder (16). The piston pump according to claim 2, characterized in that   The supply cylinder (16) has an outer ring body (42), and the outer ring body has at least one hole (36) connected to the pressure line (34) on the outside, leading to the ring nozzle (32). Piston pump according to any one of the preceding claims, characterized in that it has a ring channel (38).   Said ring channel (38) is bounded on the inside by the outer surface of the supply cylinder or on the outer surface of the inner pipe (40) which extends axially to the supply cylinder and on the outside by the inner surface of the outer ring body (42) The piston pump according to claim 3 or 4, wherein a boundary is defined.   At the end face, the supply cylinder (16) is followed by an inner pipe (40), which engages a recess in the outer ring body (42) that opens inward, together with the ring nozzle (32) and the ring. 6. A piston pump according to any one of claims 1 to 5, characterized in that the limit of the flow path (38) is defined.   The piston pump according to any one of claims 3 to 6, characterized in that the ring channel (38) has at least one ring-shaped cross-section extension (50).   8. A piston pump according to claim 7, characterized in that the ring channel (38) has two ring-shaped cross-section extensions spaced from each other.   The supply cylinder (16) is characterized by a control device that responds to the stroke direction and / or position of the supply piston (20), and a control valve that is arranged in the pressure line (34) according to an output signal of the control device. The piston pump as described in any one of Claims 1-8.   10. A piston pump according to claim 9, characterized in that the control valve arranged in the pressure line (34) opens during the suction stroke of the supply piston (20) and closes before the pressing stroke.   Piston pump according to claim 9 or 10, characterized in that the control valve is formed as a directional valve, preferably magnetically controllable via a supply piston (20).   Two supply cylinders (16), each having a ring nozzle (32) in its orifice region (12), are provided, and these ring nozzles (32) actuate the control valve during the suction stroke of the supply piston (20). The piston pump according to claim 1, wherein each of the lubricants can be filled into a supply cylinder that can be controlled in a reverse cycle.   The inner pipe (40) comprises a neck (44) projecting radially in the rear and is supported between the two ring surfaces (46, 48) of the supply cylinder (16) and the outer ring body (42). The piston pump as described in any one of Claims 5-12 characterized by the above-mentioned.   Operation of the piston pump for concentrated material, in which the concentrated material is alternately sucked into the supply cylinder (16) opened on one side during the suction stroke and then out of the supply cylinder and pushed out to the pressure supply line during the next pressing stroke Method, characterized in that the lubricant is injected into the supply cylinder (16) for each suction stroke.   15. A method according to claim 14, characterized in that the lubricant is injected into a separation region between the concentrated material and the inner surface of the supply cylinder.   16. A method according to claim 14 or 15, characterized in that the lubricant is injected all around the inner surface of the supply cylinder.   17. A method according to any one of claims 14 to 16, characterized in that the lubricant injection is interrupted during the pressing stroke.   18. The method according to any one of claims 14 to 17, wherein each piston of the first and second supply cylinders is controlled in a reverse cycle to perform a suction stroke and a pressing stroke. Lubricant is injected into the supply cylinder and the injection of lubricant is interrupted during each pressing stroke.

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