JPH05505440A - radial piston pump - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] radial piston pump The invention relates to a radial piston pump according to the preamble of claim 1.

This radial piston pump is DE-O33930248 (IP-1656) It is more well known.

An object of the present invention is to reduce wear and pulsation in the above-mentioned known radial piston pump. The aim is to ensure a minimal and simple construction in this case.

The solution to this problem is obtained by the measures specified in the characterizing part of claim 1. So Its characteristics are as follows. In other words, an extremely large discharge chamber is connected to the casing peripheral wall and the cylinder. between the outer casing and an important part of the cylinder, namely the cylinder casing. The top is manufactured as a separate structural part and assembled into the cylinder casing. A discharge valve can be installed in the front, and the cylinder cup is larger than the piston. diameter so that it can be assembled without risk of alignment errors.

The present invention will be explained below with reference to one embodiment shown in the drawings.

A radial piston pump is illustrated in cross section. radial piston pump is arranged within the cylindrical casing wall. Concentric to casing peripheral wall 1 There is axis 2. An eccentric disc 3 is rotatable around this shaft 2. This eccentric disk A support 4 is freely rotatably supported on 3. The support body 4 has a polygonal shape, The number of sides is equal to the number of bisf tons. Each surface 5 of the support body 4 is attached to the end surface of the piston 6. are in contact.

The piston 6 is slidably guided in a guide casing (cylinder casing) 7. It is. The outer and inner shapes of the guide casing are polygonal in cross-sectional view. The guide casing 7 is therefore a polygonal ring. Polygon On each side of the guide casing has a cylindrical guide hole in the illustrated embodiment; The inner bore is oriented radially with respect to the axis 2. One piston 6 is installed in each guide hole. being guided. The wall thickness of the guide casing is smaller than the overall length of the piston 6. this The width of the inner chamber of the polygonal ring is matched to the width of the support 4 and the guide cage so that the polygon inside the housing forms a stop for the polygon of the support 4. It is made up of. The support 4 is therefore relative to the cylinder casing 7. Do not perform rotational movements.

The inner chamber 14 of the guide body is connected to a suction channel (not shown) of the pump. piston 6 is constructed as a hollow cylinder, which is open on the radially outer end face and has a radial The inner end face is closed. Each piston 6 has one suction window 13 in the side wall. Only 211 is shown in Figure 1, and this is due to the small piston movement. square in order to ensure as large a suction cross section as possible. There is.

The guide casing 7 has cylinder cups 8 on its outer periphery, which are connected at one end. It is a cylindrical body that is closed at face 17 and open at the other end face. each cylinder The cup can be connected to the guide body by means of individual screws. Yet another fixed form As a formula, a spring force is applied to the cylinder cup in the intermediate chamber between the outer circumferential wall 1 and the guide body 7. It is also possible to tighten it by For this reason, the end face of each cylinder cup is It is curved outwards and has a spring-elastic structure, resulting in a chain end surface. is the outer circumference! ! ! 1 is elastically supported. Alternatively or additionally, the casing The peripheral wall of the ring should also be able to be pressed outward in a spring-elastic manner in the support area. can be done. Furthermore, alternatively or additionally, the spring-elastic pressure-spring element It is also possible to insert an element between the cylinder cup and the outer circumferential wall.

Each cylinder cup has a radial discharge passage 12. Each cylinder cup The valve band 10 is surrounded by a valve band 10 made of plastic or steel. It elastically surrounds the cylinder cup. Therefore, each valve The pad 10 is formed between the outer periphery of the guide casing and the inner periphery of the casing peripheral wall 1. It acts as a check valve for the discharge chamber 11 that is in contact with the discharge chamber 11. This discharge chamber is extremely thick (, It acts as a buffer chamber. The discharge chamber is connected to a discharge passage.

Each piston is supported by a compression spring 18 on the end wall 17 of its cylinder cup. ing. This causes each piston to be pressed against the surface of the support 4 facing the piston. , and outwardly by the rocking movement of the support surface of the support and inwardly by the spring force 18. I'm moved. This is due to the fact that the end surface of the piston is in surface contact with the side surface of the polygon. This prevents the support 4 from rotating together with the eccentric disk 3. For example, dirt If they rotate together, the polygonal surface reaches the radially outer Gaien point position. The corner edges in between impinge on the opposite inner walls of the guide casing. In this case, the eccentric disk The axial width of is larger than the piston diameter. The inner wall essentially holds the support 4 Works as a stopper. This eliminates dirt between the eccentric disk and the support. Relative motion occurs. As a result, the support body 4 is pushed back again by the spring force of the piston. Then, surface contact between the polygonal surface of the support and the end surface of the piston is again achieved.

Screws serve as one means of fixing the cylinder cup on the guide body. . This is illustrated in the cylinder cup shown at the top of the drawing.

In the cylinder cup shown at the bottom right of the drawing, the cylinder cup has a closed end face. At the end opposite to the side, it has a bushing 16 having a thread on its outer periphery. guidance The guide hole in body 7 is correspondingly enlarged and also has a thread, so that the corresponding The cylinder cup can be screwed into the guide body 7.

In the screwed-in state, the end wall 17 of the cylinder cup is no longer part of the casing circumferential wall 1. Do not come into contact with.

Another fixation type is the end of the cylinder cup! W17 becomes elastic ing. This type of fixation is illustrated in the remaining cylinder cups. S The height of the Linder cup is chosen in this case as follows: That is, the cylinder A cup is supported between the guide body 7 and the inner periphery of the casing peripheral wall in a spring-elastic manner. The feet of the Linder cup are selected so that they are pressed against the outside polygon of the guide body 7. It is.

Instead of or in addition to the spring-elastic configuration of the end face 17, a spring An element, for example a disc spring, is inserted between the end face 17 and the casing circumference 1, and the so that the under cup 8 comes into contact with the opposing polygonal surface of the guide body 7 in a spring-elastic manner. It is also possible to

FIG. 2 shows further means for preventing the supports 4 from rotating together. It is shown. In FIG. 2, a notch 19 is machined in one end wall of the support 4. Ru. A pin 20 is inserted into this notch 19, and this pin 20 is inserted into the pump casing. is fixed to a lid (not shown). This pin 20 and notch 19 are axially suitable for A further alternative is shown in dashed lines in FIG. In this case the support 4 has one radial notch 21, which has a polygonal surface and It is provided outside the range of the contact surface between the piston and the polygonal surface. Inside this notch 21 , a pin 22 protruding radially from the cylinder casing 7 is inserted. Ru.

Summary book radial piston pump A radial piston pump has a guide casing in which A piston (6) is guided radially. Guide casing radially outwards a cylinder cup is mounted on the cylinder cup; The darcup surrounds the piston in a pressure-tight manner. The casing cassob is placed on top. The guide body surrounded by the casing is surrounded by the casing peripheral wall (1) and The pump discharge chamber is formed with the singe peripheral wall.

international search report international search report DE　9200044 S^　55647

Claims (1)

[Claims] 1. A radial piston pump, the piston (6) of which has radial guidance. It is movable within the cylinder casing (7) and is moved by the eccentric disc (3). The cylinder casing (7) is The casing is surrounded by a casing peripheral wall (1) and forms a discharge chamber (11) with the casing peripheral wall. In this type, the cylinder casing (7) has a pin on its outer periphery. A cylinder cup (8) is provided in the range of the stone guide, and the cylinder cup (8) (8) is a discharge chamber between the casing peripheral wall (1) and the cylinder casing (7). (11) and has a discharge hole (12) and a valve (10). A radial piston pump featuring 2. The cylinder cup (8) is a cylindrical body, and the discharge hole is a radial hole. , and each cylinder cup has its outer periphery in the radial direction as a discharge valve (10). 2. Pump according to claim 1, characterized in that it is surrounded by a band. 3. Each cylinder cup (8) is threadedly connected to the cylinder casing (7). The pump according to claim 1 or 2, characterized in that: 4. Each cylinder cup serves as a bushing (16) as a piston in the cylinder casing. The pump according to claim 1 or 2, characterized in that it can be fitted into a ton guide. . 5. The cylinder cup is threaded into the piston guide of the cylinder casing. 5. Pump according to claim 4, characterized in that it is threaded. 6. The cylinder cup (8) is connected to the casing peripheral wall (1) and the cylinder casing ( 7) is elastically tightened by a radial spring between each cylinder. - the radially outwardly facing end face (17) of the cup and/or the casing circumferential wall (17); ) is configured as a spring and/or a cage corresponding to each cylinder cup. elastically deflected in the radial direction between the housing peripheral wall and the cylinder cup end surface (17). 3. Pump according to claim 1, characterized in that a spring element is inserted. P. 7. A support is disposed on the eccentric disk of the pump, and the support has a polygonal configuration. and a stopper is provided inside the cylinder casing. The par enters the range of motion of the polygon edge of the support, but the polygon of the support Claims 1 to 6 characterized in that it does not intrude into the range of motion of the center line of the surface. The pump according to any one of the preceding items. 8. The inner cross section of the cylinder casing is configured in a polygonal shape corresponding to the support. In this case, the difference between the diagonals is smaller than the eccentric distance, so the stopper 8. Pump according to claim 7, characterized in that it is formed.