RU2110765C1 - Smooth adjustable snap gauge - Google Patents

Abstract

FIELD: check of various diameters and dimensions. SUBSTANCE: snap gauge is composed of body, immobile heel, mobile inserts with measurement jaws and insert locator. Inserts are composed of carriages and pendulum levers. Turn axle of each pendulum lever is put on carriage. Butt of long arm of lever carries measurement jaw. Each lever interacts with compensating element that takes up clearance in axis of turn and with power member that limits effort of contact of measurement jaws with tested part. Signal indicators are mounted for movement along levers in slots of pendulums of levers. Snap gauge can be manufactured so that immobile heel and pendulum levers are slewed in opposite directions. EFFECT: expanded technological capabilities and prolonged service life of snap gauge. 2 cl, 5 dwg

Description

 The invention relates to measuring equipment and may find application in instrumentation and mechanical engineering.

 Various smooth adjustable staples are known, customizable in bore and non-bore sizes. For example, a bracket containing a housing, sliding inserts on which measuring jaws are made, a sliding mechanism and inserts clamps (US patent N 2984013, CL 33-146, 1961).

 However, in this design, the inserts are very rigidly fixed, since during the insertion of the staple onto the controlled part, great efforts can arise to deploy the inserts relative to the point of their attachment - fixing on the case. In these brackets there is a factor of subjectivity of size control, which manifests itself especially strongly in the control of thin-walled parts and parts made of soft materials: with nothing but the requirements of the instruction, the effort to insert the bracket on the part is not limited and depends almost exclusively on the physical qualities of the controller. In addition, wear of the measuring jaws due to sliding friction on the controlled part is noted with unlimited efforts to insert the clamp on the part.

 The closest technical solution to the proposed one is a smooth adjustable bracket containing a housing, movable inserts with measuring jaws, insert retainers and a fixed heel (GOST 2216-84 Caliber. Part 1. - M., 1989, p. 40-41 replenishment 2) . In this design, as in the previous one, the factor of “subjectivity” of control is retained, since the issue of limiting the efforts of the controller when inserting the bracket on the part is not resolved, and the conditions for wear of the measuring jaws from sliding friction on the controlled part are preserved.

 The objective of the invention is the creation of a smooth adjustable staples with advanced technological capabilities and enhanced operational properties.

 The technical result is to ensure the objectivity of dimensional control on the parts and increase the performance of the bracket.

 The problem is achieved due to the fact that in a smooth adjustable bracket consisting of a body, a fixed heel, movable when adjusting the inserts, measuring jaws and clamps of the inserts, according to the invention, the inserts are made integral in the form of carriages and pendulum arms, each of which has a pivot axis on the carriage, and at the end of the long arm there is a measuring sponge, and each of them interacts with the compensating element of the clearance sample in the axis of rotation and with the power element providing eniya contact force measuring jaws controlled part. Signal flags are installed in the longitudinal grooves of the pendulum arms with the possibility of their movement along the arms, and a screen is installed under the flags in the housing and slots are made.

 In addition, the bracket can be made in the caliber version for controlling internal surfaces, in which the fixed heel and measuring jaws on the pendulum arms are deployed in opposite directions, and slots on the housing for signal flags can be made on the end surface T.

 Implementation of a smooth adjustable bracket design with movable inserts consisting of carriages and pendulum arms that are moved during adjustment, which carry measuring jaws having elements of the selection of gaps in the rotation axes, as well as signal elements that record the results of dimensional control (“suitable” or “defective” ") allows you to ensure the objectivity of the control of dimensions on the parts, excluding the subjective factor of the controller due to the possibility of applying unlimited effort when entering the bracket on the controlled part. This design makes it possible to increase the performance of the bracket by reducing the wear of the measuring jaws from friction against the controlled part with a limited cocking force.

 Compared with the known technical solutions, the proposed design of the bracket has a clear advantage, as it expands its technological capabilities and increases its operational properties.

 In FIG. 1 shows a smooth adjustable bracket, side view; in FIG. 2 - the same, longitudinal section; in FIG. 3 - the same, transverse section; in FIG. 4 is a diagram of the deflection of the pendulum arm of the bracket; in FIG. 5 - the proposed bracket, made in the form of a caliber to control the internal dimensions, an embodiment.

 Smooth adjustable bracket contains a housing 1, on which the heel 2 is fixedly mounted, which acts as a stationary measuring sponge. In the guides of the housing 1, two carriages 3 and 4 are mounted with the possibility of movement, bearing the pendulum arms 5 and 6 with measuring jaws 7 and 8. The pendulum arms 5 and 6 are mounted on the carriages 3 and 4 using the rotation axes 9, and interact with compensating elements 10 of the selection of the gap, providing a choice of gaps in the axis of rotation 9, and with power elements 11, for example spring, providing a limitation of the contact force of the measuring jaws with the controlled part and the return of the levers to their original position. The power elements 11 are configured for a certain force of input of the bracket on the part, stipulated by the instruction or technical conditions for controlling a specific range of sizes of the parts.

 The carriages 3 and 4 are mounted relative to the housing 1 by means of latches 12, for example screw (Fig. 3). In the longitudinal grooves of the pendulum arms 5 and 6 (Fig. 1), signal flags 13 and 14 are installed. In the housing 1, under the flags 13 and 14, a screen 15 is installed and slots 16 and 17 are made, through which flags 13 and 14 and part of the screen 15 can be viewed Signal flags and screen are colored, for example, in red and white, respectively.

 A variant of a smooth adjustable staple-caliber designed to control internal surfaces is depicted in FIG. 5, where the fixed heel 2 and the measuring jaws 7 and 8 on the pendulum arms are deployed in opposite directions. In this embodiment, the caliber slots on the housing for the signal flags are made on the surface T.

The adjustment of the bracket is smooth, adjustable in size, by means of end measures to the limiting passage P and impassable H dimensions (Fig. 1), while
A is the minimum controlled size;
ΔA is the bracket adjustment interval;
A + ΔA is the maximum controlled size.

 The latches 12 are loosened, the carriages 3 and 4 are moved until the measuring jaws 7 and 8 come in contact with the end measures mounted on the fixed heel 2, and are clamped by the latches 12 relative to the housing 1.

 When the bracket is connected to the controlled part with a stationary measuring sponge on the heel 2, they are in contact with the part and without interruption of the contact they advance the bracket to the part.

 If the part is made fit for the passage size P, the bracket moves on to the part without touching it with the measuring sponge 7. Through the slot 16 on the housing 1, the white color of the screen 15 is visible without changes.

 If the passage size is a part defect, i.e. If its size is oversized, then when a smooth adjustable bracket moves to the part, the measuring sponge 7 first comes into contact with the controlled part at the contact point, and then deviates together with the pendulum lever 5, which rotates on the pivot axis 9, overcoming the resistance force of the power element 11. When the pendulum deviates of the lever, the contact point K (Fig. 4) describes the trajectory along the falling arc (points K-K '), as if reducing the gap between the measuring jaws 7 and 8. In this case, the signal flag 13 (Fig. 1) also deviates along with the lever 5 m and covers the slot 16 on the case 1: Now through the slot 16 instead of the white color of the screen 15 is viewed red flag 13, a marriage certificate details of communicating size.

 In the case when the controlled part is made fit for the passage size, as mentioned above, the controlled part passes under the measuring sponge 7, not touching it, and fits to the measuring sponge 8, configured for non-passing controlled size N.

 If the part is fit for a passageless size, then the bracket, when moving onto the part with a measuring sponge 8, first touches the surface of the part and then deviates together with the pendulum lever 6, which rotates on the axis of rotation 9. In this case, as in the first case, the signal flag 14 is rejected, and through the slot 17 the white color of the screen 15 is visible. This indicates the suitability of the part in a controlled size.

 If the part is made with underestimation in impassable size, and a smooth adjustable bracket passes without touching the part with measuring sponge 8, then the pendulum lever 6 remains in its original position, and the red color of the flag continues to flash in the slot 17, indicating the marriage of the part.

 After each deviation, the pendulum arms 5 and 6 return to their original position under the action of the power elements 11.

 Since the power elements 11 have a certain resistance force, recommended for the selected interval of controlled sizes, the input force of a smooth adjustable bracket on the controlled part is limited by this force and does not depend on the physical qualities of the controller. The limitation of the effort of introducing the staples to the controlled part leads to a decrease in the friction of the part on the measuring jaws and, therefore, reduces their wear, thereby increasing the service life of the staple.

 Compensating elements 10, constantly pressing the pendulum arms 5 and 6 to the axis of rotation 9, provide a constant selection of gaps in the axis of rotation and exclude the influence of possible backlash on the measurement results.

 When reconfiguring a smooth adjustable bracket to other sizes, the carriages 3 and 4 can move up and down, increasing or decreasing the size between the fixed heel 2 and the measuring jaws 7 and 8 within ΔA (Fig. 1). In this case, when the pendulum arms 5 and 6 are moved, the signal flags 13 and 14 remain between the housing 1 and the screen 15, and the legs of the flags slide along the longitudinal grooves of the pendulum arms.

 The smooth adjustable bracket (caliber) shown in FIG. 5 and designed to control the internal dimensions of the parts, works in the same way as the bracket in FIG. one.

Claims (3)

 1. A smooth adjustable bracket containing a housing, a fixed heel, movable inserts during adjustment, measuring jaws and insert locks, characterized in that the inserts are made integral in the form of carriages and pendulum arms, each of which has a pivot axis mounted on the carriage and at the end a long arm a measuring jaw is made, and each of the levers interacts with a compensating element for sampling the gap in the axis of rotation and with a power element that ensures the limiting contact force of the measuring jaws with the control detail.  2. The bracket according to claim 1, characterized in that the signal flags are installed in the longitudinal grooves of the swingarm arms with the possibility of their movement along the arms, and a screen is installed under the flags in the housing and slots are made.  3. The bracket according to claim 1, characterized in that the fixed heel and the measuring jaws on the pendulum arms are deployed in opposite directions.

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