RU225613U1 - Pipe cutter - Google Patents

Abstract

The utility model relates to hand-held devices for cutting large-diameter plastic pipes used in plumbing systems. A pipe cutter for cutting plastic pipes contains a body hinged on a clamping device with the possibility of rotation around the pipe axis and having a guide bar. The cutting device holder is located in the bar and can be moved towards the pipe. The clamping device is fixed to the pipe. The cutting device of the holder contains a cutting tool for chamfering and a cutting tool for cutting, located separately from each other and made in the form of plates. The cutting edge of the cutting tool is located on a plane perpendicular to the axis of the pipe. Increased productivity is achieved by removing pipe material from the working area directly during the chamfering process. 3 salary f-ly, 4 ill.

Description

The utility model relates to hand-held devices (pipe cutters) for cutting large-diameter plastic pipes (in particular, 110 mm) used in plumbing systems.

To connect plastic sewer pipes to each other in engineering plumbing, pipes with a socket are used. To facilitate insertion into the socket, the edge of the cut pipe must contain a chamfer on the outer surface of the pipe.

A device for cutting pipes is known - patent No. EP1236529, B23D 21/10, publ. 09/04/2002, in which the cutting tool is presented in the form of a roller, and the tool holder has a guide with which the chamfering tool can be used only for the inner surface of the pipe. Using a roller cutting tool is more suitable for cutting pipes with a large wall thickness (for example, more than 3.4 mm), and when working with pipes of standard thickness (for example, less than 2.8 mm), the pipe wall bends under the influence of the cutting roller, due to why too much time is spent on pipe cutting.

The closest technical solution is a device for cutting pipes (prototype) - application No. EP0672493, B26D 3/16, B23D 21/10, publ. 09.20.95, containing a clamping device in the form of two halves of a ring that can be fixed to the pipe. The ring-shaped housing is hinged on the clamping device with the possibility of rotation around the pipe. The guide bar is located on the outside of the housing, protrudes outward from it and is directed radially relative to the axis of the pipe. The holder and cutting tool in the form of a plate are located along the guide bar and can be moved towards the pipe using a spindle and handle. The cutting tool includes a cutting edge and a chamfering edge, wherein the cutting edge is located in front of the chamfering edge towards the pipe.

The disadvantage of this device is that during the cutting process, when the cutting edge is immersed in the pipe cavity, the user is forced to apply a fairly large force to rotate the pipe cutter body. This is due to the fact that the shape of the cutting tool does not allow the cutting tool to freely plunge into the pipe cavity and cutting the pipe to length is carried out by cutting and removing the pipe material. Also, when cutting a pipe, the cut material sometimes has to be removed by hand, otherwise it can become lodged between the pipe and the bevel edge.

The technical result is the creation of a universal pipe cutter that makes it possible to increase labor productivity by removing pipe material from the working area directly during the chamfering process.

The specified technical result is achieved by the fact that in a pipe cutter for cutting plastic pipes, containing a housing pivotally located on a clamping device with the possibility of rotation around the axis of the pipe and having a guide bar in which a holder of the cutting device, a clamping device, is located with the ability to move towards the pipe, mounted on the pipe, the cutting device of the holder contains a cutting tool for chamfering and a cutting tool for cutting, located separately from each other and made in the form of plates, each with at least one cutting edge, while the cutting edge of the cutting tool is located on plane perpendicular to the pipe axis. The cutting edge of both cutting tools is formed by two edges located symmetrically at an angle of 10-20° to one another. In this case, the cutting tool for cutting has a pointed working part with a thickness of 0.5-2 mm relative to the length of the pipe, and the cutting edge of the chamfering tool lies on a plane that is located at an angle of 1-7° to the axis of the pipe.

The essence of the technical solution is illustrated by drawings.

Fig. 1 - top view of the pipe cutter, partial section

Fig. 2 - side view of the pipe cutter, partial section.

Fig. 3 - top view of the cutting tool holder during the pipe cutting process, partial section.

Fig. 4 - side view of the cutting tool holder in the process of chamfering a pipe, partial section.

As shown in Figure 1, the pipe cutter consists of a body 1 in the form of a ring and a clamping device 2, which is fixedly mounted on the pipe 3. In this case, the body 1 is able to rotate freely relative to the clamping device 2 around the axis of the pipe 3.

The guide bar 4 is part of the housing 1, which is located on its outer side, protrudes outward from it and is directed radially relative to the axis of the pipe 3. The guide bar 4 has a recess 5, in which a holder 6 is placed for cutting tools 7 and 8, which can be use a segment of a utility knife blade.

The cutting tool 7 is used to cut the pipe to length and is fixedly fixed to the holder 9 using a clamp 10, and the chamfering tool 8 is fixed using a clamp 11 (Fig. 2). The holder 6 has the ability to move in the recess 5 in the direction of the pipe 3 by rotating the handle 12. The body 1 has a side 13, guided by which, you can align the cutting tool 7 with the location of the future cut of the pipe 3.

Figure 3 shows a holder 9 of cutting tools 7 and 8 in the process of cutting a pipe 3. The cutting tool 7 and the chamfering tool 8 are made in the form of plates consisting of a base 14, which is attached to the holder 9 and a pointed working part 15. Cutting the edge 16 of the working part 15 is formed by two edges 17, located symmetrically at an angle of 10-20° to one another.

Figure 4 shows a holder 9 of cutting tools 7 and 8 when chamfering pipe 3.

The thickness of the working part 15 of the cutting tool 7 is 0.5-2 mm, which makes it easier to immerse the cutting tool 7 into the cavity of the pipe 3 during its cutting and allows the pipe 3 to be cut without removing the material of the pipe itself. This results in a reduction in the physical force applied to the handle 12 by the user to rotate the pipe cutter body 1.

The cutting edge of the chamfering tool 8 lies on a plane located at an angle of 1-7° to the pipe axis. This allows you to direct the cut pipe material in the form of chips away from the working area, thereby reducing the likelihood of clogging it.

The pipe cutter works as follows. First, the pipe cutter is fixed to the pipe 3 using a clamping device 2, guided by the side 13 and the mark of the future cut. Next, the handle 12 and the holder 9 of the cutting tools 7 and 8 are rotated, moving in the recess 5, approaching the pipe 3. As soon as the cutting tool 7 touches the outer surface of the pipe 3, they begin to rotate the body 1 around the pipe 3 and the clamping device 2. The cutting tool 7 enters the cavity of pipe 3 without the formation of chips. By twisting the handle 12 and rotating the body 1 by the required number of turns, the pipe 3 is cut. Then the chamfering tool 8 is brought to the edge of the cut pipe 3. By twisting the handle 12 and rotating the body 1 around the pipe 3, the chamfer is removed. The chips generated during chamfering do not get stuck in the working area and are easily removed.

The advantages of the proposed technical solution compared to the prototype are:

1. Labor productivity increases due to the removal of pipe material from the working area during the chamfering process.

2. The cut pipe material in the form of chips can be easily removed due to the fact that the cutting tool and the chamfering tool are made separately, as well as the angle of the edge of the chamfering tool.

3. Reducing the physical effort required by the user to rotate the housing around the pipe.

Practice has shown the performance of this pipe cutter design. The stated technical result was achieved: a universal pipe cutter was created that allows increasing labor productivity by removing pipe material from the working area directly during the chamfering process.

Claims (4)

1. A pipe cutter for cutting plastic pipes, containing a body hinged on a clamping device with the possibility of rotation around the axis of the pipe and having a guide bar in which a cutting device holder is located with the ability to move towards the pipe, a clamping device mounted on the pipe, characterized in that that the cutting device of the holder contains a cutting tool for chamfering and a cutting tool for cutting, located separately from each other and made in the form of plates with a cutting edge, while the cutting edge of the cutting tool is located on a plane perpendicular to the axis of the pipe. 2. The pipe cutter according to claim 1, characterized in that the cutting edge of both cutting tools is formed by two edges located symmetrically at an angle of 10-20° to one another. 3. Pipe cutter according to claim 2, characterized in that the cutting tool has a pointed working part with a thickness of 0.5-2 mm relative to the length of the pipe. 4. Pipe cutter according to claim 3, characterized in that the cutting edge of the chamfering tool lies on a plane that is located at an angle of 1-7° to the pipe axis.