RU34352U1 - Core drill - Google Patents

Description

Core drill / li / / b

The utility model relates to medical equipment, and more specifically, to devices for making holes in bone fragments, skeleton bones in the treatment of their fractures, in particular, in osteosynthesis.

Spiral drills are known (see Arshinov V.A., Alekseev G.A. “Metal cutting and cutting tools M., Engineering, 1967, p. 206, Fig. 173, and also GOST 10902-77), containing a shank , pheiku, the working part with a chip spiral groove, cutting edges, ribbons and core.

When drilling hollow bones, the drill rotates around its axis with the simultaneous supply of a tool along it, which, when the cutting edges interact with the bone, leads to the formation of a cylindrical hole in the latter.

A pedad of this design during drilling, especially of hollow bones, is trauma to the patient’s soft tissues during the entire drilling process and the possibility of chips and bone fragments getting into the bone cavity, which can lead to an inflammatory process in this place after surgery, which, in turn, will require a second operation.

The indicated drawbacks were partially eliminated in drill bits for core drilling (see Arshinov VA, Alekseev GA “Metal cutting and cutting tools M., Mechanical Engineering, 1967, p. 240, Fig. 198) containing a hollow shank , neck, working part, in which the working cutting edges of the knives protrude beyond the outer diameter of the shank, the inner diameter of the hole and the side of the end

drill, while a trapezoidal slotted knife follows a flat stripping.

When the drill rotates around its axis and longitudinally feeds along the axis of the nolsh, an annular cavity is cut out.

The disadvantage of this device is that in the process of cutting bones, especially hollow, chips or bone fragments are formed, as if going in front of the drill, which leads to their falling into the bone cavity, because due to the rotation of the drill, the chip, when it enters the bone cavity, scatters through the cavity or penetrates into the spongy layer located between the compact layers of the bones, which can lead to inflammatory processes in the interosseous cavity, i.e. again, an additional operation is required, which increases the duration of treatment and additionally injures the patient's psyche.

The objective of this utility model is to reduce soft tissue injuries and shorten treatment time by ensuring that chips and bone fragments enter the bone cavity.

The task is achieved by the fact that in the drill for annular drilling containing a hollow shank with a working part, on which the end and inner cutting edges are located, the inner cutting edge at the top of the drill is made with inverse taper, and special chip grooves are made along the inner cylindrical surface of the shank, moreover, a cavity with a reduced pressure is attached to the non-working end of the drill.

In FIG. 1 shows a general view of a drill for annular drilling with a cut, and in FIG. 2 - view And on the end working surface.

The drill for annular drilling contains a hollow shank 1 on the front working part of which is made slots forming the end cutting edges 2 and on the inner conical input part

internal working edges 3, made with inverse taper at an angle f, and on the inner cylindrical cavity of the shank, spiral flutes 4 are made at an angle w, while a cavity of a reduced pressure P. is connected to the inactive end of the shank 1.

Drill for core drilling works as follows. Drill 1 is installed in the drill chuck (for example, DM drill, code 08.02.710. State experimental enterprise “CITO. M., 2001, p. 30) and when it is turned on, the drill receives torque and is supplied by In this cl) D1ae handed, comes into contact with bone tissue that is open for contact, for example, by cutting the patient’s soft tissues. Due to the interaction with the end cutting edge 2 with the bone tissue and as a result of its compliance, the process of cutting the drill 1 into the bone takes place. The resulting chips, bone fragments, as a result of rarefaction (P) in the inner cavity of the shank 1, are pressed to the surfaces forming the inner edge 3, which is made with inverse taper at an angle φ, which leads to the penetration of processing waste into the inner cavity of the shank 1 on the cylindrical the surface of which is made of spiral grooves 4, along which the mixture of struvle and bone fragments rushes up to the opposite end of the shank 1. The presence of an angle of inclination from the spiral chip removal grooves 4 drive in reduced axial forces during penetration of the drill bit 1 into the bone, decreasing the moment of the resistance forces and ensures reliable removal of chips even when the load is removed during passage of the drill through the bone cavity or sponge layer, i.e., chips do not enter the bone cavity.

over the shank, the soft tissue injuries of the patient are reduced, and given that this drill is used to guide the spokes through the bone tissue and to make holes for various types of screws during osteosynthesis, i.e. its diameter lies in the range of 14-5 mm, then the chips are completely discharged through the internal spiral channel, because it is additionally affected by the forces caused by the presence of a cavity of reduced pressure, as well as the components of the forces associated with an increase in the force of introduction of the drill into the bone, i.e. virtually eliminates the possibility of chips entering the cavity of the resulting hole.

Claims (1)

A drill for annular drilling, containing a hollow shank with a working part, on which the end and inner cutting edges are located, characterized in that the inner cutting edge at the top of the drill is made with inverse taper, and spiral chip grooves are made along the inner cylindrical surface of the shank, and to the idle a cavity with a reduced pressure is attached to the end of the drill.