JP3140090U - Clamping force measurement sensor - Google Patents

Abstract

The present invention provides a mold clamping force measuring sensor that can stably hold a strain sensor for measuring mold clamping force, has excellent durability, has excellent output characteristics, and can prevent disconnection of a signal cable.
A mold clamping force measurement sensor is a signal cable in which a strain sensor is brought into close contact with an end surface of an elastic fitting body fitted into a central portion of a sensor holding body, and the end portion is soldered to the strain sensor. 5b is an elastic insertion body 12, one sensor holding body 2 which penetrates the thick part of the central portion and is led out from the central portion, and a strain sensor on the end surface of the elastic insertion body fitted in the central portion. The signal cable, which is in close contact and soldered to the end of the strain sensor, is connected to the elastic fitting body, the thickened portion of the central portion is passed through and the other sensor holding body is led out from the central portion, and hinged A mold clamping force measurement sensor 1 which is connected to the outer periphery of the tie bar and is attached to the outer periphery of the tie bar to measure the mold clamping force.
[Selection] Figure 3

Description

  The present invention relates to a mold clamping force measurement sensor, and more particularly to a mold clamping force measurement sensor that measures strain generated in a tie bar used in a mold support mechanism of an injection molding machine.

  For example, a mold of an injection molding machine is generally divided into a plurality of parts, and is used by being clamped together during molding. Further, in the mold clamping device, a tie bar is connected to a mold support mechanism for the mold, and a mold clamping force acts on the tie bar to cause distortion corresponding thereto.

  Conventionally, various types of clamping force measurement sensors that measure the strain of a tie bar while being in close contact with the tie bar have been proposed.

  An example of a conventional mold clamping force measurement sensor will be outlined with reference to FIGS.

  FIG. 12 shows a part of a conventional mold clamping force measurement sensor 51. This mold clamping force measurement sensor 51 has a square bar shape and a semi-elliptical ring shape, and is composed of, for example, a strain gauge on the inner peripheral surface of the center portion. One sensor holding body 52 holding the strain sensor 55 and another sensor holding body (not shown) formed in the same manner as the one sensor holding body 52 are connected to each other so as to be openable and closable by a hinge connection so as to form an elliptical ring as a whole. It is configured.

  The sensor holding body 52 is attached to the outer periphery of a tie bar 20 connected to a mold support mechanism (not shown) for the mold, and the clamping force acting on the tie bar 20 is measured by the strain sensor 55. It is configured as follows. In FIG. 12, reference numeral 55b denotes a signal cable (conductive wire) having a two-piece structure.

  The strain sensor 55 is provided with a sensor portion such as a strain gauge on a film-like sensor holding piece, for example, and, as shown in FIG. 13, the end portions of the two signal cables 55b are respectively connected to the sensor portion. Connected by two soldering portions 54 slightly bulging outward from the sensor holding piece, the strain signal generated in the sensor portion is connected to the outside of the mold clamping force measuring sensor 51 via a signal cable 55b having two configurations. Is transmitted to a signal processing circuit (not shown) provided in FIG.

  Next, the holding structure of the strain sensor 55 in the sensor holding body 52 will be described with reference to FIGS.

  FIG. 13 shows an arrangement relationship between the elastic fitting 53 such as a rubber seat and the strain sensor 55, and FIG. 14 is a cross section of the sensor holding body 52, the strain sensor 55, the signal cable 55 b, the elastic fitting 53 and the tie bar 20. Is shown.

  As shown in FIG. 12, a screw receiving hole 56 for a fitting cylindrical screw body 80 is provided in the central portion of the sensor holding body 2 as shown in FIG.

  Further, as shown in FIGS. 12 and 17, two through holes 53a are provided in the recessed portion provided from the inner peripheral surface side toward the receiving screw hole 56 side in the central portion of the sensor holding body 52. The elastic fitting body 53 is fitted.

  Further, two cable insertion holes 52 a are provided in a thick portion between the receiving screw hole 56 and the recessed portion into which the elastic fitting body 53 is fitted in the sensor holding body 52.

  Then, the strain sensor 55 shown in FIG. 13 is disposed in close contact with the inner peripheral side end face of the elastic fitting 53, and the signal cable 55b is connected to the two through holes 53a, the two cable insertion holes 52a, and the receiving screw. It is configured to lead out through the hole 56. A protective film (not shown) is attached to the outer surface of the strain sensor 55.

  Next, the elastic fitting body 53 will be described with reference to FIGS. 15 to 18. The elastic fitting body 53 is formed, for example, in the shape of an ellipse by using, for example, a rubber material.

  As described above, two through-holes 53a having a diameter of about 0.7 mm are formed in the elastic fitting body 53 at a predetermined interval, and the sensor holding body 52 in the elastic fitting body 53 is formed. As shown in FIGS. 15 to 18, two elongated rectangular receiving grooves 53 b that contact the two soldered portions 54 are formed on the end surface (upper surface in FIG. 15) located on the inner peripheral side. The two through holes 53a are in communication with each other.

  The two receiving grooves 53b are, for example, formed with a long side of 3.5 mm, a short side of 1 mm, and a depth of about 0.5 mm.

  The two signal cables 55b pass through the two through holes 53a, the two cable insertion holes 52a, and the two through holes on the bottom 56a of the receiving screw hole 56 in the sensor holding body 52. A part of the hole 53 a is fixed by, for example, brazing at the opening position of the hole 53 a to form a connection portion 57, and further led out to the outside through the receiving screw hole 56.

  In the conventional mold clamping force measurement sensor 51 described above, the two soldered portions 54 in the two-configuration signal cable 55b are simply brought into contact with the two elongated rectangular receiving grooves 53b. As shown in FIG. 13, the strain sensor 55 does not adhere to the end face of the elastic fitting body 53 and slightly floats (a state where a gap is generated), and the position of the strain sensor 55 becomes unstable. As a result, as shown in FIG. 19, when a force (pressing force: indicated by an arrow) is applied from the sensor holding body 52 or the tie bar 20 to the sensor unit constituting the strain sensor 55, the sensor unit is displaced, tilted, or damaged. And the like, the durability of the mold clamping force measurement sensor 51 is impaired, and the output characteristics are also deteriorated.

  Further, in the conventional mold clamping force measurement sensor 51, a part of the two signal cables 55 b is partially opened at the opening positions of the two through holes 53 a on the bottom 56 a of the receiving screw hole 56 in the sensor holding body 52. For example, since the connection portion 57 is formed by being fixed by brazing or the like, the two signal cables 55b have no allowance for external force, and force (pressing force) from the sensor holding body 52 or the tie bar 20 is the strain sensor. When acting on the sensor section constituting 55, a force acts directly on the two signal cables 55b. As a result, as shown in FIG. 20 and FIG. 21, soldering at two places on the two signal cables 55b is performed. There is a disadvantage that the portion 54 and its vicinity are deformed, broken, etc. and become disconnected.

  Patent Document 1 discloses a mold clamping force detection provided with a frame member that can be fitted to and removed from the side of a tie bar, a sensor urging means that presses a strain sensor incorporated in the frame member and held at a protruding end against the tie bar, and the like. A device has been proposed.

However, this Patent Document 1 also does not consider the stability of the position of the strain sensor itself and the prevention of disconnection of the signal cable connected to the strain sensor.
JP 2003-112344 A

  The problems to be solved by the present invention are that the strain sensor that measures the clamping force acting on the tie bar can be stably held, has excellent durability, and has excellent output characteristics. There is no mold clamping force measurement sensor that prevents cable breakage.

  The mold clamping force measurement sensor according to the present invention is a square bar-like and semi-elliptical ring, and a strain sensor is brought into close contact with the end face of the elastic fitting body fitted with the end face facing the inner peripheral surface of the center part, The signal cable soldered to the end of the strain sensor is connected to the elastic fitting, the one thicker part of the sensor that passes through the thick part of the central part and is led to the outside from the central part, and a square bar shape, and A semi-elliptical ring, a strain sensor is brought into close contact with the end face of the elastic fitting body fitted with the end face facing the inner peripheral surface of the center part, and the signal cable having the end connected to the strain sensor by soldering is elastically fitted. The other sensor holding body which penetrates the thick part of the central part and is led out from the central part is connected to the other end side so that it can be opened and closed by hinged coupling, and the other end side is opposed. The end parts are fixed with screws. As a shape exhibiting an elliptical ring shape, a mold clamping force measurement sensor for measuring a clamping force acting on the tie bar by attaching both sensor holding bodies to the outer periphery of the tie bar, and the elastic fitting body The most important feature is that an immersion groove for immersing the bulging portion of the soldered portion is provided on the end surface.

  According to the first aspect of the present invention, an immersing long groove for immersing the bulging portion in the soldered portion between the strain sensor and the signal cable is provided on the end surface of the elastic fitting body for closely contacting the strain sensor. Therefore, the strain sensor can be placed in close contact with the elastic fitting in a flat state without any bulge on the outer surface side, and can be held in a stable state with excellent durability and excellent output characteristics. It is possible to provide a mold clamping force measurement sensor that can be used.

  According to the second aspect of the invention, the effects of the first aspect of the invention can be achieved, and a part of the signal cable can be fixed and held in the middle of the wiring path of the signal cable in the sensor holding body with a sufficient margin. Since the buffer connection portion is provided, the force from the tie bar side can be buffered by the bending deformation of the signal cable, and the mold clamping force measurement sensor that can avoid the disconnection of the signal cable can be provided.

  According to the invention of claim 3, the signal cable having the end connected to the strain sensor by soldering is passed through the through hole provided in the elastic fitting, the cable insertion hole provided in the thick part of the central part is passed through, As in the case of the contrivance according to claim 2, the strain sensor of the strain sensor is based on a configuration in which it is led out from the central portion through a receiving screw hole for a fitting cylindrical screw body provided on the outer peripheral side of the central portion. It is possible to provide a mold clamping force measurement sensor capable of ensuring durability by maintaining stability, maintaining output characteristics, and avoiding disconnection of a signal cable.

  According to the fourth aspect of the present invention, two recessed long grooves that are expanded in a tapered shape are provided on the end face of the elastic fitting body so that the two bulging portions of the soldered portion are respectively immersed, and the wiring path As in the case of the device according to claim 3, based on a configuration in which a buffer connection portion for fixing and holding a part of each of the two signal cables is provided at the bottom of the receiving screw hole in the middle, with a margin, It is possible to provide a mold clamping force measurement sensor capable of ensuring durability by stably holding a strain sensor, maintaining output characteristics, and avoiding disconnection of a signal cable.

  The present invention can stably hold a strain sensor that measures the clamping force acting on the tie bar, has excellent durability, has excellent output characteristics, and further prevents signal cables from being disconnected. The object of the present invention is to provide a mold clamping force measuring sensor.

  The present invention is a square rod-like and semi-elliptical ring shape, in which a strain sensor is brought into close contact with the end surface of the elastic fitting body fitted with the end surface facing the inner peripheral surface of the center portion, and the end portion is soldered to the strain sensor. A signal cable connected to the elastic fitting body, one sensor holding body that is led out from the central portion through the thick portion of the central portion, a quadrangular rod-shaped and semi-elliptical ring, A strain sensor is brought into close contact with the end surface of the elastic fitting body fitted with the end surface facing the peripheral surface, and a signal cable having an end portion soldered to the strain sensor is connected to the elastic fitting body and the central portion. Connect the other sensor holding body that penetrates the thick part to the outside from this center part so that it can be opened and closed by hinge coupling at one end side, and fix the opposite end parts at the other end side with screws It has a configuration that exhibits an elliptical ring shape as a whole As a shape, a mold clamping force measurement sensor that mounts both sensor holding bodies on the outer periphery of a tie bar and measures a mold clamping force acting on the tie bar by the strain sensor, the sensor provided on an end face of the elastic fitting body An immersion long groove for immersing the bulging part of the soldered part, and a buffer connection part for fixing and holding a part of the signal cable with a bend in the middle of the wiring path of the signal cable in the sensor holding body, The above object is realized by a configuration having

  Hereinafter, a mold clamping force measuring sensor according to an embodiment of the present invention will be described in detail with reference to the drawings.

  First, with reference to FIG. 1 thru | or FIG. 11, the clamping force measuring sensor 1 which concerns on the Example of this invention is demonstrated.

  As shown in FIG. 1, the mold clamping force measurement sensor 1 according to the present embodiment has a square bar shape and a semi-elliptical ring shape, and has one sensor holding that holds a strain sensor 5 made of, for example, a strain gauge on the inner peripheral surface of the central portion. The body 2 and the other sensor holding body 3 having a square bar shape and a semi-elliptical ring shape and holding a strain sensor 5 made of, for example, a strain gauge on the inner peripheral surface of the central portion are connected to each other by using a hinge 4. It is configured so as to be openable and closable so as to exhibit an elliptical ring shape as a whole.

  The two sensor holders 2 and 3 are mounted on the outer periphery of a tie bar 20 connected to a mold support mechanism (not shown) for the mold, and a clamping force acting on the tie bar 20 is applied to the strain sensor 5. 5 for measurement. In FIG. 1, reference numeral 5 a denotes a protective film for the strain sensors 5, 5 affixed to the inner peripheral surfaces of the sensor holders 2, 3, and 5 b denotes a two-signal cable.

  More specifically, the one sensor holding body 2 is provided with a screw insertion recess 7 connected to a through screw hole 6 penetrating to each end face in the vicinity of both end faces, and the strain sensor 5 facing the inner peripheral surface at the center. Holding.

  The other sensor holding body 3 is provided with a receiving screw hole 8 opposed to the through screw hole 6 provided in the one sensor holding body 2 on both end faces, and the strain sensor 5 facing the inner peripheral surface at the center. keeping.

  The two sensor holders 2 and 3 thus configured are mounted on the outer periphery of the tie bar 20, and the receiving screw holes 8 from the through screw hole 6 side at the opposite end portions on the release side which are the hinge 4 side and the other end side. A tightening screw 10 is screwed on the side, and is fastened to the outer periphery of the tie bar 20, and the strain sensor 5, 5 is brought into close contact with the outer periphery of the tie bar 20, and a mold clamping force acting on the tie bar 20 is measured by the strain sensor 5, 5. It is like that.

  The hinge 4 is formed, for example, with a substantially rectangular and thin elastic rubber body 9 using a set screw 11 between the one end sides of the sensor holding bodies 2 and 3 in the circumferential direction (the other end sides of the sensor holding bodies 2 and 3 are separated from each other). Or in the approaching direction).

  Next, the holding structure of the strain sensor 5 in the sensor holding body 2 will be described in detail with reference to FIGS.

  FIG. 2 is an enlarged view of the strain sensor 5 and the signal cable 5b constituting the mold clamping force measuring sensor 1, and FIG. 3 is the sensor holder 2, the strain sensor 5, and the signal cable 5b. An enlarged cross section of the elastic fitting 12 such as a seat and the tie bar 20 is shown.

  As shown in FIG. 2, the strain sensor 5 is provided with, for example, a sensor portion 13 such as a strain gauge on a film-like sensor holding plate 13a, and an end of a signal cable 5b having two configurations with respect to the sensor portion 13. The parts are connected to each other by two soldering parts 14 that slightly bulge outward from the sensor holding plate 13a, and the strain signal generated in the sensor part 13 is transferred to the mold clamping force via the signal cable 5b having two structures. The signal is transmitted to a signal processing circuit (not shown) provided outside the measurement sensor 1.

  As shown in FIG. 3, a screw receiving hole 16 for a fitting cylindrical screw body 15 is provided in the center portion of the sensor holding body 2 on the outer peripheral surface side thereof.

  Further, as shown in FIG. 3, the sensor holding body 2 has an elastic fit in which two through holes 12a are provided in a recessed portion provided from the inner peripheral surface side toward the receiving screw hole 16 side, as shown in FIG. The insert 12 is fitted.

  Further, two cable insertion holes 2a are provided in a thick portion between the receiving screw hole 16 and the recessed portion into which the elastic fitting body 12 is fitted in the sensor holding body 2. Then, the strain sensor 5 shown in FIG. 2 is disposed in close contact with the inner peripheral side end face of the elastic fitting body 12, and the signal cable 5b is connected to the two through holes 12a, the two cable insertion holes 2a, and the receiving screw. It is configured to lead out through the hole 16. The protective film 5 a is attached to the outer surface of the strain sensor 5.

  Next, the elastic fitting body 12 will be described with reference to FIGS. The elastic fitting body 12 is formed, for example, by using a rubber material in the shape of an ellipse having an overall shape of, for example, a width of about 16 mm, a depth of 6 mm, and a height of about 6 mm.

  As described above, two through holes 12a having a diameter of about 0.7 mm are drilled at a predetermined interval in the elastic fitting body 12, and the sensor holding body 2 in the elastic fitting body 12 is formed. As shown in FIGS. 6 to 8, two oblong-shaped grooves 12 b having an elliptical shape for immersing the two soldered portions 14 are formed on the end surface (upper surface in FIG. 6) located on the inner peripheral side. The two through holes 12a are provided in communication with each other.

  The two immersion long grooves 12b have, for example, a long side of 3.5 mm, a short side of 1 mm, a depth of about 0.5 mm, and a tapered shape that expands toward the end surface.

  Further, end portions 12c opposite to the through holes 12a in the two immersion long grooves 12b are formed in an arc shape having a radius of about 0.5 mm.

  By forming the two immersion long grooves 12b into the shape described above, when the two immersion long grooves 12b are arranged in close contact with the elastic fittings 12, as shown in FIG. 14 bulge portions are immersed in the two immersing long grooves 12b, whereby the strain sensor 5 is arranged in close contact with the elastic fitting body 12 in a flat state without any bulging. To be able to.

  Further, with respect to the two signal cables 5 b, a buffer connection portion 17 is provided inside the sensor holder 2.

  That is, as shown in FIG. 5, the two signal cables 5b pass through the two through holes 12a, the two cable insertion holes 2a, and the screw receiving holes 16 in the sensor holding body 2. One end of the bottom portion 16a is bent along the bottom portion 16a, for example, about 4 mm to 6 mm, and a part of the bottom portion 16a is fixed to the surface of the bottom portion 16a by, for example, brazing to form the buffer connection portion 17. It is led out through the hole 16.

  Each element including the strain sensor 5 on the other sensor holding body 3 side has the same configuration as that described above.

  Next, with respect to the operation of the mold clamping force measurement sensor 1 according to the present embodiment having the above-described configuration, referring to FIGS. 10 and 11 and Table 1, the manner in which the strain sensor 5 is attached to the elastic fitting body 12 and The operation of the buffer connection portion 17 will be mainly described.

  According to the mold clamping force measurement sensor 1 according to the present embodiment, as described above, the attachment mode of the strain sensor 5 to the elastic fitting 12 is in the two immersion long grooves 12b provided in the elastic fitting 12. The bulging portions of the two soldered portions 14 constituting a part of the strain sensor 5 are immersed, and the outer surface side (tie bar 20 side) of the strain sensor 5 adheres in a flat state without any bulge. Thus, the sensor unit 13 constituting the strain sensor 5 can be held in an extremely stable state.

  As a result, when the strain of the tie bar 20 is actually measured by the mold clamping force measurement sensor 1 according to the present embodiment, as shown in FIG. 10, force (compression force: indicated by an arrow) from the sensor holding body 2 or the tie bar 20. ) Acts on the sensor unit 13 constituting the strain sensor 5, the mold clamping force measuring sensor 1 is excellent in durability because the sensor unit 13 is not displaced, tilted or broken, and has excellent durability. Can be provided.

  Further, with respect to the two signal cables 5b connected to the strain sensor 5, since the buffer connection portion 17 as described above is provided in the region of the bottom portion 16a of the receiving screw hole 16, for example, as shown in FIG. When a force (compression force: indicated by an arrow) from the tie bar 20 side acts on the sensor unit 13 constituting the strain sensor 5, the two signal cables 5b are bent in the vicinity of the buffer connection portion 17 in the bottom portion 16a. The part is deformed into a state where it floats with a margin, and the force from the tie bar 20 side is buffered (released), so that the disconnection of the two signal cables 5b in the soldered part 14 and the vicinity thereof is surely avoided. Is done.

  For the four types of samples having a configuration in which the two signal cables 5b provided with the strain sensor 5, the elastic fitting body 12, and the buffer connection portion 17 are attached to the sensor holders 2 and 3 of this embodiment, respectively. Table 1 below shows the results of individually repeating (300 times) the test of measuring the strain of the tie bar 20 while closely contacting the tie bar 20. The disconnection was confirmed every 20 times.

  As is apparent from Table 1, it was found that the position of the sensor part (strain gauge) was stable in all cases after 300 tests, and there was no inclination, no breakage, and no disconnection. The output characteristics of the strain sensor 5 were also good.

  The present invention can be applied not only for measuring the strain force of the tie bar of the mold clamping device described above but also for measuring equipment for measuring the strain force acting on a columnar or cylindrical member.

1 is a schematic front view of a mold clamping force measurement sensor according to an embodiment of the present invention. It is a perspective view which expands and shows the distortion sensor and signal cable which comprise the mold clamping force measuring sensor which concerns on a present Example. It is a partial expanded sectional view of a sensor holding body, a strain sensor, a signal cable, an elastic fitting body, and a tie bar constituting the mold clamping force measurement sensor according to the present embodiment. It is a fragmentary sectional view which shows the contact | adherence state with respect to the elastic insertion body of the strain sensor in the mold clamping force measuring sensor which concerns on a present Example. It is a fragmentary sectional view which shows the buffer connection part of the signal cable in the mold clamping force measuring sensor which concerns on a present Example. It is the perspective view seen from the end surface side which faces the tie bar side of the elastic fitting body in the mold clamping force measuring sensor which concerns on a present Example. It is the top view seen from the end surface side which faces the tie bar side of the elastic fitting body in the mold clamping force measuring sensor which concerns on a present Example. It is a front view of the elastic fitting body in the mold clamping force measuring sensor which concerns on a present Example. It is a side view of the elastic fitting body in the mold clamping force measuring sensor which concerns on a present Example. It is explanatory drawing which shows the action state of the force to the distortion sensor in the mold clamping force measuring sensor which concerns on a present Example. It is explanatory drawing which shows the releasing operation | movement of the force by the buffer connection part of the signal cable in the mold clamping force measuring sensor which concerns on a present Example. It is a partial expanded sectional view of a sensor holding body, a strain sensor, a signal cable, an elastic fitting body, and a tie bar constituting a conventional mold clamping force measurement sensor. It is a fragmentary sectional view which shows the contact | adherence state with respect to the elastic fitting body of the strain sensor in the conventional mold clamping force measuring sensor. It is a fragmentary sectional view which shows the connection part of the signal cable in the conventional mold clamping force measuring sensor. It is the perspective view seen from the end surface side which faces the tie bar side of the elastic fitting body in the conventional mold clamping force measuring sensor. It is the top view seen from the end surface side which faces the tie bar side of the elastic fitting body in the conventional mold clamping force measuring sensor. It is a front view of the elastic fitting body in the conventional mold clamping force measuring sensor. It is a side view of the elastic fitting body in the conventional mold clamping force measuring sensor. It is explanatory drawing which shows the action state of the force to the distortion sensor in the conventional mold clamping force measuring sensor. It is sectional drawing which shows the action state of the force to the distortion sensor in the conventional mold clamping force measuring sensor. It is explanatory drawing which shows the deformation | transformation state of the signal cable in the conventional mold clamping force measuring sensor.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Type clamping force measuring sensor 2 Sensor holding body 3 Sensor holding body 4 Hinge 5 Strain sensor 5a Protective film 5b Signal cable 6 Through screw hole 7 Screw insertion recessed part 8 Receiving screw hole 9 Elastic rubber body 10 Clamping screw 11 Set screw 12 Elastic fitting Insert body 12a Through hole 12b Immersion long groove 12c End portion 13 Sensor portion 13a Sensor holding plate 14 Soldering portion 15 Inserted cylindrical screw body 16 Receiving screw hole 16a Bottom portion 17 Buffer connection portion 20 Tie bar

Claims (4)

A square bar-shaped and semi-elliptical ring, a signal in which a strain sensor is brought into close contact with the end surface of the elastic fitting body fitted with the end surface facing the inner peripheral surface of the center portion, and the end portion is soldered and connected to the strain sensor One end of the cable that is inserted into the elastic fitting body, the thick portion of the central portion and led to the outside from the central portion, a square rod-like, semi-elliptical ring, and an end surface on the inner peripheral surface of the central portion A strain sensor is brought into intimate contact with the end face of the elastic fitting body that is fitted so that the signal cable is connected to the strain sensor by soldering the end portion thereof. The other sensor holding body that penetrated and led out to the outside from the central part is connected to be openable and closable by hinge coupling at one end side, and the opposite end parts at the other end side are screwed and fixed, As a whole, it has an elliptical ring shape , A mold clamping force measuring sensor for measuring the mold clamping force acting on the tie bar by mounting the both sensor holders on the outer circumference of the tie bar by the strain sensor,
A mold clamping force measuring sensor, wherein an immersion long groove for immersing the bulging portion of the soldered portion is provided on an end face of the elastic fitting body. A square bar-shaped and semi-elliptical ring, a signal in which a strain sensor is brought into close contact with the end surface of the elastic fitting body fitted with the end surface facing the inner peripheral surface of the center portion, and the end portion is soldered and connected to the strain sensor One end of the cable that is inserted into the elastic fitting body, the thick portion of the central portion and led to the outside from the central portion, a square rod-like, semi-elliptical ring, and an end surface on the inner peripheral surface of the central portion A signal sensor having an end portion soldered to the strain sensor is connected to the end surface of the elastic fitting body fitted with the elastic fitting body, and the thick portion of the central portion is connected to the strain sensor. The other sensor holding body that has been penetrated and led out to the outside from the center part is connected to be openable and closable by hinge coupling at one end side, and the opposite end parts at the other end side are screwed and fixed, As a whole, it has an elliptical ring shape , A mold clamping force measuring sensor for measuring the mold clamping force acting on the tie bar by mounting the both sensor holders on the outer circumference of the tie bar by the strain sensor,
An immersion long groove for immersing the bulging portion of the soldered portion provided on the end face of the elastic fitting, and
In the middle of the wiring path of the signal cable in the sensor holding body, a buffer connection part for fixing and holding a part of the signal cable with a bending margin;
A mold clamping force measuring sensor characterized by comprising: A square bar-shaped, semi-elliptical ring, a signal having a strain sensor in close contact with the end face of the elastic fitting body fitted with the end face facing the inner peripheral surface of the central part, and the end part soldered to the strain sensor Through the through hole provided in the elastic fitting body, the cable insertion hole provided in the thick portion of the central portion, and the receiving screw hole for the fitting cylindrical screw body provided on the outer peripheral side of the central portion A strain sensor is closely attached to the end surface of the elastic fitting that is fitted with the end surface facing the inner peripheral surface of the central portion, in the shape of a square bar and a semi-elliptical ring. In addition, a signal cable having an end soldered to the strain sensor is passed through a through hole provided in the elastic fitting, a cable insertion hole provided in the thick part of the central part, This center part passes through the receiving screw hole for the fitting cylindrical screw body provided. The other sensor holding body led out to the outside is connected to each other by hinge coupling so that it can be opened and closed, and the opposite ends on the other end side are fixed with screws. As a mold clamping force measurement sensor that mounts both sensor holders on the outer periphery of a tie bar and measures the clamping force acting on the tie bar with the strain sensor,
Each of two immersion long grooves for immersing the bulging portion of the soldered portion provided on the end face of the elastic fitting,
A buffer connection portion for fixing and holding a part of the signal cable at a bottom portion of the receiving screw hole in the middle of the wiring path of the signal cable in the sensor holding body with a bending margin;
A mold clamping force measuring sensor characterized by comprising: A strain sensor is brought into close contact with the end surface of an elliptical-shaped elastic fitting body that is a quadrangular rod-like and semi-elliptical ring and is fitted with the end surface facing the inner peripheral surface of the center portion, and an end portion is attached to the strain sensor. Two signal cables connected by soldering are passed through two through holes provided in the elastic fitting and two cable insertion holes provided in the thick part of the central part, and provided on the outer peripheral side of the central part. One sensor holding body led out from this center through a receiving screw hole for a fitting cylindrical screw body, and a square rod-like, semi-elliptical ring, with the end face facing the inner peripheral surface of the center A strain sensor is brought into close contact with the end surface of the inserted elliptical elastic fitting, and two signal cables whose ends are soldered to the strain sensor are provided on the elastic fitting. Through hole, through the two cable insertion holes provided in the thick part of the central part, The other sensor holding body, which is led out from the center through a receiving screw hole for a fitting cylindrical screw body provided on the outer peripheral side, is connected to each other so that it can be opened and closed by hinged connection. The opposite ends on the end side are fixed to each other with screws. As a whole, an elliptical annular shape is used. Both sensor holders are mounted on the outer periphery of the tie bar, and the clamping force acting on the tie bar is measured by the strain sensor. A mold clamping force measuring sensor,
Each of the two long immersion grooves expanded in a tapered shape with a long elliptical shape into which the two bulging portions of the soldered portion provided on the end face of the elastic fitting body are immersed;
A buffer connection portion for fixing and holding each part of the two signal cables at the bottom of the receiving screw hole in the middle of the wiring path of the two signal cables in the sensor holding body with a bending margin; ,
A mold clamping force measuring sensor characterized by comprising:

Images