JP4934285B2 - Concrete mixer - Google Patents

Description

  The present invention relates to a concrete mixer for producing ready-mixed concrete by mixing various concrete materials such as gravel, sand, cement, water, and an admixture.

2. Description of the Related Art Conventionally, a vibratory mixer in which kneading is performed while applying vibration to a concrete material in a kneading tank is known. For example, in Patent Document 1 (Japanese Patent Publication No. 53-43257), in a mixer in which a fixed kneading shaft is faced from above in a rotating pan-type kneading tank, a vibrator is provided at the base end of the kneading shaft. A mixer is described in which the kneading shaft at the tip of the kneading shaft and the kneading shaft is vertically vibrated. Patent Document 2 (Japanese Utility Model Laid-Open No. 59-190333) describes a mixer in which a vibrator is attached to the bottom of the kneading tank so that the entire kneading tank is vibrated. In such a vibratory mixer, it is expected that the strength of the concrete after being kneaded is increased by kneading the concrete material put into the kneading tank while giving an appropriate vibration.
Japanese Patent Publication No.53-43257 Japanese Utility Model Publication No.59-190333

  By the way, as the vibration mixer, not only the above-mentioned ones but also various other ones are conceivable, but in any case, those capable of more efficiently applying vibration to the concrete material are required. In consideration of maintenance, it is preferable to consider that the vibration is efficiently transmitted only to the concrete material and not transmitted to the mixer device such as a drive motor as much as possible.

  In view of the above points, an object of the present invention is to provide a concrete mixer that can efficiently vibrate concrete material and is suitable for producing high-quality concrete.

In order to solve the above-mentioned problems, the concrete mixer according to claim 1 of the present invention is provided with vibration applying means for applying vibration only in the circumferential direction to a kneading shaft disposed in the kneading tank, and the vibration a concrete mixer for kneading various concrete material by rotating the kneading shaft by the driving motor while vibrating the mixing blade that is disposed radially kneading shaft and its surroundings by providing means, said vibrating means is kneaded shaft A pair of rotary vibrators are arranged on a vibration plate attached to the shaft end of each of the rotary vibrators, and the rotary shafts of the unbalanced weights of the rotary vibrators are connected by a timing belt and synchronized with each rotary type. the positional relationship of the unbalanced weights of the vibration motor is adjusted so as to be symmetrical, in so that to impart vibration to only the circumferential direction by offsetting the vibration of the radial direction with respect to the kneading shaft Is characterized in that form was.

Moreover, concrete mixer according to claim 2, the pair of rotary vibration machine, and arranged in a manner to sandwich the mixed kneading shaft by canceling the vibration in the radial direction with respect to mixed kneaded axis only circumferentially It is characterized by being configured to so that to impart vibration to.

Moreover, concrete mixer according to claim 3, said pair of rotary vibration machine, circumferentially by offsetting the vibration of the radial direction with respect to the kneading shaft and arranged shifted from the axis of the mixing kneading shaft It is characterized by being configured to so that to impart vibration to only.

According to a fourth aspect of the present invention, there is provided the concrete mixer according to the fourth aspect, wherein the pair of rotary vibrators are disposed so as to sandwich the vibration plate so as to cancel the radial vibration with respect to the kneading shaft, and only in the circumferential direction. It is characterized by being configured to so that to impart vibrations.

The concrete mixer according to claim 5 is characterized by comprising vibration suppressing means for suppressing the vibration from the vibrator from reaching the drive motor side for rotating the kneading shaft .

According to a sixth aspect of the present invention, in the concrete mixer, the vibration suppressing means includes a vibration plate in which a sprocket that is rotationally driven by a drive motor is loosely fitted to one end of the kneading shaft, and the sprocket and the kneading shaft are attached to the shaft end portion. And are connected through an elastic body .

The concrete mixer according to claim 7, further comprising: a vibration plate for fixing a vibrator on the wall surface of the kneading tank, the inner surface of the vibration plate facing the inside of the kneading tank, while the vibration plate and the wall surface of the kneading tank And is fixed through a vibration isolator .

According to the concrete mixer of the present invention, the kneading shaft disposed in the kneading tank is provided with vibration applying means for applying vibration only in the circumferential direction thereof, and is radially arranged around the kneading shaft and its periphery by the vibration applying means. In a concrete mixer for kneading various concrete materials by rotating a kneading shaft by a driving motor while vibrating a kneading blade provided , the vibration applying means is a pair of rotary types on a vibration plate attached to the shaft end of the kneading shaft. It is made up of a vibrator, and the rotation axis of the unbalanced weight of each rotary vibrator is connected and synchronized by a timing belt, and the positional relationship of the unbalanced weight of each rotary vibrator is made symmetrical. to adjust, since the so that to impart vibrations by offsetting the vibration of the radial direction to the circumferential direction only to the kneading shaft, imposing a load on such a kneading shaft Ku such as through the kneading shaft and a number of mixing blade provided thereto can be spread efficiently vibrating the concrete material, it is possible to obtain suitably high quality concrete to improve the kneading performance.

  In addition, since it has vibration suppression means that suppresses the vibration from the vibrator from reaching the drive motor side that drives the kneading shaft to rotate, it can prevent failure and breakage due to vibration of the drive part of the mixer as much as possible. This is advantageous in terms of maintenance.

  In addition, a vibration plate for fixing the vibrator to the wall surface of the kneading tank is provided, and the inner surface side of the vibration plate is faced to the inside of the kneading tank, while the vibration plate and the wall surface of the kneading tank are fixed via a vibration isolating material. Therefore, the concrete material can be vibrated more directly and efficiently than the vibration plate, and the kneading performance can be suitably improved to obtain high-quality concrete, and the vibration to the mixer itself such as the kneading tank is Since it is absorbed and weakened by the vibration isolator, it is possible to prevent failure and breakage due to vibration of the mixer device as much as possible, which is advantageous in terms of maintenance.

  In the concrete mixer of the present invention, for example, a kneading shaft is disposed horizontally in a kneading tank, and the kneading shaft is rotated by a drive motor to stir and mix various concrete materials for kneading. In a mixer or the like, for example, a pair of rotary vibrators are disposed on one end side of the kneading shaft so as to sandwich the kneading shaft. In addition, a timing belt is wound around and connected to the rotation shaft of the unbalanced weight of each rotary vibrator to synchronize the rotation cycle of the unbalanced weight, and the positional relationship of the unbalanced weight of each rotary vibrator is determined. Adjust the mounting direction of each weight so that it is always symmetrical. By so doing, vibrations in the radial direction of the kneading shaft can be canceled and vibration can be applied only in the circumferential direction, that is, only in the direction in which the kneading shaft can be rotated. It tries to prevent bearings and other parts from being damaged by vibration.

  Then, when producing concrete with the mixer, the kneading shaft driving motor is driven to rotate the pair of rotary vibrators provided on the kneading shaft to apply vibration to the kneading shaft, thereby driving the kneading shaft. Is rotated in a predetermined direction, and concrete materials are sequentially charged into the kneading tank. The concrete material thrown into the kneading tank is repeatedly stirred and mixed while receiving vibrations from the kneading shaft and its numerous kneading blades, whereby suitable kneading is performed and discharged as high-quality concrete.

  As described above, since the concrete material is kneaded while applying a vibration without applying a load as much as possible to the kneading shaft of the concrete mixer, the efficiency of the concrete material is improved through the kneading shaft and its many kneading blades. A sufficient vibration can be distributed well, and the kneading performance is suitably improved, and an increase in the strength of the concrete after kneading can be expected.

  Further, vibration suppressing means for suppressing the vibration of the kneading shaft from reaching the drive motor side is provided. For example, a sprocket that is rotationally driven by a drive motor is loosely fitted to one end of the kneading shaft, and a vibration plate that fixes a pair of vibrators is attached to the shaft end of the kneading shaft. Further, the vibration plate and the sprocket are connected via a spring.

  And, when manufacturing concrete, while driving the vibrator and generating vibration, by driving the drive motor and rotating the sprocket, by rotating the sprocket through the spring by rotating the sprocket, Finally, the kneading shaft equipped with the vibration plate is rotated. At this time, the vibration of the vibrator is directly transmitted to the kneading shaft side via the vibration plate, and the kneading shaft is surely vibrated in the rotating direction, while the sprocket side is mostly driven by a spring in the middle thereof. It is absorbed and weakened, and no strong vibration is transmitted to the drive motor.

  In this way, while reliably applying vibration to the kneading shaft of the mixer, the vibration of the drive motor is prevented from being transmitted to the drive motor as much as possible. This is advantageous in terms of maintenance.

  In addition, a vibration plate for fixing the vibrator to the wall surface of the kneading tank is provided, and the inner surface side of the vibration plate is made to face the inner wall surface of the kneading tank, for example, while facing the inner side of the kneading tank. And the wall of the kneading tank are fixed with bolts through vibration-proof rubber.

  When manufacturing concrete, while driving the vibrator of the kneading tank to vibrate the vibration plate, the kneading shaft driving motor is driven to rotate the kneading shaft, and the concrete material is sequentially put into the kneading tank. I will continue to introduce. At this time, the vibration of the vibration plate is directly transmitted to the inside of the kneading tank where a part of the plate faces, while the kneading tank itself is largely absorbed and weakened by the anti-vibration rubber interposed therebetween. There is no strong vibration transmitted to the device. The concrete material put into the kneading tank is agitated and mixed while receiving strong vibrations directly from the vibration plate, thereby being suitably kneaded and discharged as high-quality concrete.

  In this way, the concrete material is kneaded while applying vibration from the vibration plate provided in the mixer kneading tank, so that sufficient vibration can be distributed directly and efficiently to the concrete material, and the kneading performance is suitably Can be expected to increase the strength of concrete after kneading. In addition, the vibration of the vibration plate is strongly transmitted to the concrete material in the kneading tank, and conversely not transmitted to the kneading tank itself as much as possible. This is advantageous in terms of maintenance.

  Embodiments of the present invention will be described below with reference to the drawings.

  Reference numeral 1 denotes a biaxial concrete mixer for kneading concrete materials such as gravel, sand, cement, water, and an admixture to produce ready-mixed concrete, and the kneading tank 2 passes through two parallel kneading shafts 3. The bearing 4 fixed to the kneading tank 2 is rotatably supported. A large number of arms 5 are radially arranged on the kneading shaft 3 in the radial direction, and kneading blades 6 having an appropriate angle are attached to the tip of the arms 5.

  A sprocket 7 is loosely fitted to one end side of one kneading shaft 3 without being fixed to the kneading shaft 3 as a rotation transmission mechanism, and a drive motor 8 is disposed on the side of the sprocket 7. The sprocket 9 provided in the drive motor 8 and the sprocket 7 loosely fitted to the kneading shaft 3 are connected by a chain 10 so that the sprocket 7 is rotated by driving of the drive motor 8. In the present embodiment, the sprocket 7 and the drive motor 8 are provided only for one kneading shaft 3, but both the kneading shafts 3 are each provided with a sprocket and a driving motor. It may be a thing.

  Further, following the sprocket 7, a gear 11 is loosely fitted and meshed with the kneading shaft 3, and the left and right kneading shafts 3 are rotated at a synchronous speed. The gear 11 and the sprocket 7 loosely fitted to the same kneading shaft 3 are integrally fixed so as to rotate together.

  A vibration plate 12 for fixing a pair of rotary vibrators, which will be described later, is attached to the shaft end portion following the gear 11 of the kneading shaft 3 to be fixed integrally with the kneading shaft 3, and the vibration plate 12 As shown in FIG. 6, a plurality of substantially L-shaped fastening pieces 13 and 14 projecting substantially concentrically from the vibration plate 12 side and from the gear 11 side, as shown in FIG. The fastening pieces 13 and 14 are coupled by being fastened with bolts 16 that are fasteners via springs 15 that are elastic bodies.

  Therefore, the driving force for rotating the sprocket 7 by the driving motor 8 is transmitted from the gear 11 to the vibration plate 12 via the spring 15 and finally transmitted from the vibration plate 12 to the kneading shaft 3. . On the other hand, the vibration from the rotary vibrator is directly transmitted to the kneading shaft 3 side via the vibration plate 12, but most of the vibration is absorbed by the spring 15 interposed between the gear 11 and the sprocket 7 side. The vibration suppressing mechanism is configured so that strong vibration is not transmitted to the drive motor 8. As a result, unnecessary vibrations of the drive motor 8 and the like are suppressed as much as possible, and failure and damage are prevented in advance, which is advantageous in terms of maintenance. Instead of the spring 15, an elastic body such as a disc spring or rubber may be employed.

  Reference numeral 17 denotes a rotary vibrator for generating vibrations. The kneading shaft 3 is sandwiched between a fixed member 18 having a pair of rotary vibrators 17 protruding from the side of the vibration plate 12 as shown in FIG. Placed and fixed. In addition, the rotation shaft 20 of the unbalanced weight 19 built in the pair of vibrators 17 is connected and synchronized by the timing belt 21, and as shown in FIG. Adjusted so that the positional relationship is always symmetrical. In this way, the vibration applying means for applying the vibration to the kneading shaft 3 only in the circumferential direction is configured.

  Accordingly, when the pair of rotary vibrators 17 are rotationally driven, as shown in FIG. 7, first, at the timing of (a), a downward excitation force acts from the left vibrator 17 in the drawing. At the same time, an upward exciting force is exerted from the right vibrator 17, and as a result, an exciting force in the left rotation direction around the kneading shaft 3 is generated in the vibration plate 12. At the next timing (b), an inward excitation force is applied from the left vibrator 17 and an inward excitation force is also applied from the right vibrator 17, and as a result, each vibrator 17. The excitation forces cancel each other out, and no excitation force is generated on the vibration plate 12 in any direction.

  At the subsequent timing (c), an upward excitation force is exerted from the left vibrator 17 and a downward excitation force is exerted from the right vibrator 17, and as a result, the vibration plate 12 has a kneading shaft. Exciting force in the clockwise direction around 3 is generated. At the last timing (d), an outward excitation force is applied from the left vibrator 17 and an outward excitation force is also applied from the right vibrator 17, resulting in each vibration. The excitation forces of the machine 17 cancel each other and cancel out, and no excitation force is generated in the vibration plate 12 in any direction.

  Thus, when the pair of rotary vibrators 17 are rotationally driven to vibrate the kneading shaft 3 via the vibration plate 12, the kneading shaft 3 does not vibrate in the radial direction but only in the circumferential direction. Since it vibrates so as to oscillate, it can be suitably vibrated without applying an excessive load to the bearing of the bearing 4 of the kneading shaft 3 or the like. Even in the middle of the steps (a), (b), (c), and (d) not shown in FIG. 7, the positional relationship of the unbalanced weights 19 of the left and right rotary vibrators 17 is Since it is always symmetric, vibrations in the radial direction of the kneading shaft 3 always cancel each other and vibrations are applied only in the circumferential direction.

  Further, an opening 22 having a predetermined size is formed in the left and right positions of the bottom surface of the kneading tank 2 and is different from the rotary vibrator 17 provided in the kneading shaft 3 so as to close the opening 22. A vibration plate 24 for fixing the vibrator 23 is provided. As shown in FIGS. 4 and 5, the vibration plate 24 to which the vibrator 22 is fixed has its inner surface facing the inside of the kneading tank 2 so as to be flush with the inner wall surface of the kneading tank 2. The periphery of the vibration plate 24 is fastened and fixed to the fixing plate 26 with bolts 27 via vibration-proof rubber 25 that is a vibration-proof material. Furthermore, the fixing plate 26 has its peripheral edge abutted against the outer wall surface of the kneading tank 2 around the opening 22 via a watertight packing 28, and both longitudinal ends of the fixing plate 26 are illustrated in FIG. As shown in FIG. 1, the packing 28 is pressed along a substantially L-shaped fixing piece 29 that is bent into a substantially L shape and the bent portion projects from the bottom surface of the kneading tank 2. The bolt 30 is fastened and fixed for watertightness.

  Therefore, when the vibrator 23 is driven, only the vibration plate 24 vibrates strongly, and the vibration force is directly transmitted as it is to the concrete material in the kneading tank 2 facing the vibration plate 24, while to the kneading tank 2 itself. The vibration isolating rubber 25 absorbs and weakens most of the vibration force, so that strong vibration is not transmitted and the mixer 1 can be prevented from being broken or damaged by vibration.

  In this embodiment, a pair of vibrators 23 attached to the left and right positions of the bottom surface of the kneading tank 2 is used. However, the present invention is not limited to this. You may make it attach to both a bottom face and a side surface, or various other places. The number of vibrators 23 may be increased or decreased as appropriate according to the size of the kneading tank 2, and the size of the vibration plate 24 may be changed as appropriate. Further, the vibrator 23 does not have to be a rotary vibrator that rotates and vibrates the unbalanced weight 19 provided in the kneading shaft 3. For example, a piston-type vibrator can be effectively employed. Can do.

  Therefore, when kneading the ready-mixed concrete using the concrete mixer of the present invention, first, the pair of rotary vibrators 17 provided on the kneading shaft 3 are respectively driven to rotate while applying vibration to the kneading shaft 3. Then, the drive motor 8 is driven to rotate the two kneading shafts 3 in opposite directions, and the vibrator 23 provided in the kneading tank 2 is also driven to vibrate the vibration plate 24. At this time, the vibration by the vibrator 17 is directly transmitted to the kneading shaft 3 side, and is strongly transmitted to many arms 5 and kneading blades 6 provided on the kneading shaft 3, while being transmitted to the driving motor 8 side. The vibration is not transmitted to the driving motor 8 strongly by being absorbed and weakened by the spring 15 interposed in the middle. Further, the vibration generated by the vibrator 23 is directly transmitted to the inside of the kneading tank 2 from the vibration plate 24, while being absorbed and weakened by the vibration isolating rubber 25 in the middle of the kneading tank 2 itself. 1 itself does not vibrate strongly.

  Then, in this state, various concrete materials are sequentially put into the kneading tank 2. The concrete material thrown into the kneading tank 2 is mixed with the kneading shaft 3, the many arms 5 and the kneading blades 6, and the kneading blade 6 that rotates while constantly receiving constant vibration from the vibration plate 24 on the bottom of the kneading tank 2. It is repeatedly kneaded and mixed, suitably kneaded, and discharged as high-quality ready-mixed concrete that can be expected to increase in strength.

  As described above, the kneading shaft 3 of the mixer 1 and the vibration plates 12 and 24 provided in the kneading tank 2 are configured to suitably generate vibrations. The vibration can be efficiently and sufficiently distributed, whereby the kneading performance is improved, and the quality of the concrete after kneading can be further improved.

  In this embodiment, a gear having a gear is used to synchronize the two kneading shafts, and the gear and the sprocket are fixed together so as to rotate together. The gear and the vibration plate are connected to each other through a spring that is an elastic body. For example, a drive motor reduction gear connected to each other by a coupling mechanism can be used. For example, a gear can be omitted, and a simple configuration in which the vibration plate and the sprocket are simply connected via a spring, which is an elastic body, can be achieved. Further, the mixer itself may be a single-shaft type instead of the biaxial type, and in that case, a simple configuration in which the gear is omitted as described above can be achieved.

  Furthermore, in this embodiment, a batch type mixer is employed, but it can also be suitably employed for a continuous type mixer or the like. In particular, the vibrator provided on the kneading tank side can be effectively employed in various types of mixers such as a pan-type mixer.

  FIG. 8 shows another embodiment of the vibration applying means for applying the vibration to the kneading shaft 3 only in the circumferential direction. One piston type vibrator 31 is placed on the vibration plate 12 and the shaft of the kneading shaft 3. The piston type vibrator 31 is arranged so as to be slightly shifted from the center, so that the advancing / retreating direction of the piston 32, that is, the vibration direction, coincides with the tangential direction of the circumference of the kneading shaft 3.

  When the piston-type vibrator 31 is driven, first, at the timing (a), a downward excitation force is exerted from the left-side vibrator 31 in the figure, and the kneading shaft 3 is naturally attached to the vibration plate 12. An excitation force is generated in the left rotation direction around the center. On the other hand, at the timing (b), an upward exciting force is applied from the vibrator 17, and naturally an exciting force in the clockwise direction around the kneading shaft 3 is generated on the vibration plate 12. In this way, when the piston-type vibrator 31 is driven to vibrate the kneading shaft 3 via the vibration plate 12, the kneading shaft 3 is swung only in the circumferential direction without vibrating in the radial direction. Therefore, it can be suitably vibrated without applying an excessive load to the bearing of the bearing 4 of the kneading shaft 3.

  FIG. 9 shows a type in which two piston-type vibrators 31 that are one in FIG. 8 are adopted, and a pair of piston-type vibrators 31 are sandwiched between the kneading shafts 3 on the vibration plate 12. Are arranged so that the vibration periods of the piston vibrators 31 are synchronized, and the excitation directions of the piston vibrators 31 are tangential to the circumference of the kneading shaft 3 and symmetrical to each other. It is configured.

  When the piston-type vibrator 31 is driven, first, at the timing (a), a downward excitation force is exerted from the left-side vibrator 31 in the drawing, and upward from the right-side vibrator 31. As a result, the vibration plate 12 generates a vibration force in the counterclockwise direction around the kneading shaft 3. On the other hand, at the timing (b), an upward exciting force is applied from the left vibrator 31 and a downward exciting force is applied from the right vibrator 31, and as a result, the vibrating plate 12 has a kneading shaft. Exciting force in the clockwise direction around 3 is generated. As described above, this embodiment can also be vibrated suitably in the same manner as described above.

  FIG. 10 shows another embodiment of the vibration applying means. A pair of rotary vibrators 17 are both slightly shifted from the axis of the kneading shaft 3 on the vibration plate 12 in the radial direction of the kneading shaft 3. The rotation shafts 20 of the unbalanced weights 19 of the rotary vibrators 17 are connected in synchronization by a timing belt, and the positional relationship of the unbalanced weights 19 of the rotary vibrators 17 is symmetrical. The vibration in the radial direction is offset with respect to the kneading shaft 3.

  When the pair of rotary vibrators 17 are driven to rotate, first, at the timing (a), a downward excitation force is applied from the left vibrator 17 in the drawing, and the right vibrator 17 is operated. Therefore, a downward exciting force is generated, and the vibrating plate 12 naturally generates an exciting force in the counterclockwise direction around the kneading shaft 3. At the next timing (b), an inward excitation force is exerted from the left vibrator 17 and an outward excitation force is exerted from the right vibrator 17, and as a result, each vibrator 17. The excitation forces cancel each other out, and no excitation force is generated on the vibration plate 12 in any direction.

  At the subsequent timing (c), an upward exciting force is exerted from the left vibrator 17 and an upward exciting force is also exerted from the right vibrator 17, and the kneading shaft 3 is naturally applied to the vibrating plate 12. Exciting force in the clockwise direction around the center is generated. At the last timing (d), an outward excitation force is applied from the left vibrator 17 and an inward excitation force is applied from the right vibrator 17, resulting in each vibration. The excitation forces of the machine 17 cancel each other and cancel out, and no excitation force is generated in the vibration plate 12 in any direction. As described above, this embodiment can also be vibrated suitably in the same manner as described above.

  FIG. 11 shows a modified type of FIG. 10, in which a pair of rotary vibrators 17 are both slightly shifted from the axis of the kneading shaft 3 and arranged in the radial direction of the kneading shaft 3. The rotating shaft 20 of the unbalanced weight 19 of the rotary vibrator 17 is connected and synchronized by a timing belt, and the positional relationship of the unbalanced weight 19 of each rotary vibrator 17 is adjusted to be symmetric, What is configured to cancel the vibration in the radial direction with respect to the kneading shaft 3 is similarly provided on the opposite side of the kneading shaft 3.

  When each rotary vibrator 17 is driven to rotate, first, at the timing of (a), the leftmost vibrator 17 in the figure exerts a downward excitation force and the second from the left. A downward exciting force is also exerted from the vibrator 17, an upward exciting force is exerted from the rightmost vibrator 17, and an upward exciting force is also exerted from the second vibrator 17 from the right. As a result, a vibration force in the counterclockwise direction around the kneading shaft 3 is generated in the vibration plate 12. At the next timing (b), an inward excitation force is applied from the leftmost vibrator 17, and an outward excitation force is applied from the second vibrator 17 from the left. From the rightmost vibrator 17, an outward excitation force works, and from the right second vibrator 17 an inward excitation force works. As a result, the excitation force of each vibrator 17 Cancel each other out, and no vibration force is generated in the vibration plate 12 in any direction.

  At the subsequent timing (c), an upward excitation force is applied from the leftmost vibrator 17, and an upward excitation force is also applied from the second vibrator 17 from the left. A downward excitation force is applied from the vibrator 17 and a downward excitation force is also applied from the second vibrator 17 from the right. As a result, the vibration plate 12 has a right centering around the kneading shaft 3. An excitation force in the rotational direction is generated. At the last timing (d), the leftmost vibrator 17 exerts an outward exciting force, and the second vibrator 17 from the left exerts an inward exciting force. In addition, an inward excitation force is applied from the rightmost vibrator 17, and an outward excitation force is applied from the second vibrator 17 from the right. As a result, the excitation force of each vibrator 17 is increased. The vibration forces cancel each other and cancel each other, and no vibration force is generated on the vibration plate 12 in any direction. As described above, this embodiment can also be vibrated suitably in the same manner as described above.

  FIG. 12 shows still another embodiment of the vibration applying means. Each of the vibration applying means 17 is arranged in parallel with the axis of the kneading shaft 3 so that the vibration plate 12 is sandwiched between the pair of rotary vibrators 17. The rotating shaft 20 of the unbalanced weight 19 of each rotary vibrator 17 is connected and synchronized by a timing belt, and the positional relationship of the unbalanced weight 19 of each rotary vibrator 17 is symmetric. It adjusts and it is comprised so that the vibration to an axial center direction may be canceled with respect to the kneading shaft 3. FIG. In FIG. 12, the diagram shown in the middle is viewed from the same direction as the upper diagram, and the diagram shown in the lower diagram is a diagram of the upper diagram viewed from the right hand.

  When the pair of rotary vibrators 17 are driven to rotate, first, at the timing (a), a downward excitation force is applied from the left vibrator 17 in the drawing, and the right vibrator 17 is operated. As shown in the figure seen from the lower right hand direction, the vibration plate 12 naturally generates an excitation force in the left rotation direction about the kneading shaft 3. At the next timing (b), an excitation force in the direction of the vibration plate 12 works from the left vibrator 17, and an excitation force in the direction of the vibration plate 12 also works from the right vibrator 17, as a result. The vibration forces of the vibrators 17 cancel each other and cancel each other, and no vibration force is generated in the vibration plate 12 in any direction.

  At the subsequent timing (c), an upward excitation force is exerted from the left vibrator 17 and an upward excitation force is also exerted from the right vibrator 17, and the vibration plate 12 is naturally attached to the rear of the vibration plate 12. An exciting force is generated in the direction, that is, in the clockwise direction around the kneading shaft 3. At the last timing (d), an excitation force in the direction opposite to the vibration plate 12 is exerted from the left vibrator 17, and an excitation in the opposite direction from the vibration plate 12 is also performed from the right vibrator 17. As a result, the excitation forces of the vibrators 17 cancel each other and cancel each other, and no excitation force is generated in the vibration plate 12 in any direction. As described above, this embodiment can also be vibrated suitably in the same manner as described above.

It is a partially cutaway front view showing an embodiment of a concrete mixer according to the present invention. It is a top view of FIG. It is a side view of FIG. It is the AA cross-sectional enlarged view which abbreviate | omitted a part of FIG. It is a principal part enlarged view of FIG. It is the BB cross-sectional enlarged view which abbreviate | omitted a part of FIG. It is explanatory drawing explaining the excitation direction by a vibrator. It is a figure equivalent to FIG. 7 of another Example. It is a figure equivalent to Drawing 7 of another example. It is a figure equivalent to Drawing 7 of another example. It is a figure equivalent to Drawing 7 of another example. It is a figure equivalent to FIG. 7 of another Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Concrete mixer 2 ... Kneading tank 3 ... Kneading shaft 5 ... Arm 6 ... Kneading blade 7 ... Sprocket 8 ... Drive motor 11 ... Gear 12, 24 ... Vibration plate 15 ... Spring (elastic body)
17, 31 ... vibrator (vibration applying means)
19: Unbalanced weight (vibration applying means)
20 ... Rotating shaft (vibration applying means)
21 ... Timing belt (vibration applying means)
22 ... Opening 23 ... Vibrator 25 ... Anti-vibration rubber (anti-vibration material)

Claims (7)

The kneading shaft disposed in the kneading tank is provided with vibration applying means for applying vibration only in the circumferential direction thereof, and is driven while vibrating the kneading shaft and the kneading blades radially disposed around the kneading shaft by the vibration applying means. a concrete mixer for kneading various concrete material by rotating the kneading shaft by use motor, the vibrating means is disposed a pair of rotary vibration machine vibration plate mounted on the shaft end of the kneading shaft The rotation shafts of the unbalanced weights of the rotary vibrators are connected and synchronized by a timing belt, and the positional relationship of the unbalanced weights of the rotary vibrators is adjusted so as to be symmetric. concrete mixers, characterized in that by canceling the vibration in the radial direction constitute a so that to impart vibrations in the circumferential direction only to The pair of rotary vibration machine was configured so that to impart vibrations in the circumferential direction only by canceling the vibration in the radial direction with respect to mixed kneaded axis and disposed in a manner sandwiching the mixed kneading shaft The concrete mixer according to claim 1. The pair of rotary vibration machine, configured so that to be juxtaposed axial center staggered in mixed kneaded axis by offsetting the vibration of the radial direction with respect to the kneading shaft imparts vibration in the circumferential direction only The concrete mixer according to claim 1. The pair of rotary vibration machine, by being configured to so that to impart vibrations by offsetting the vibration of the radial direction to the circumferential direction only to the kneading shaft and disposed in a manner sandwiching the vibrating plate The concrete mixer according to claim 1. It claims 1 to 4 Concrete mixer according vibrations characterized by comprising suppressing vibration suppressing means from affecting the driving motor side for rotating the kneading shaft from the vibrator. The vibration suppressing means is configured by loosely fitting a sprocket that is rotationally driven by a driving motor on one end side of the kneading shaft, and connecting the sprocket and a vibration plate attached to the shaft end portion of the kneading shaft via an elastic body. concrete mixer according to claim 5, characterized in that. A vibration plate for fixing a vibrator on the wall surface of the kneading tank was provided, and the inner surface side of the vibration plate was faced to the inside of the kneading tank, while the vibration plate and the wall surface of the kneading tank were fixed with a vibration isolating material. The concrete mixer according to claim 1, wherein:

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