JP2014126090A - Pump mounted type speed change gear and pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pump mounted type speed change gear capable of reducing time and effort to required for the work to change a change gear ratio.SOLUTION: Plural sets of gear trains 17, and 18 for changing the speed of rotation at an input shaft 15 side and transmitting the speed of rotation to an output shaft 16 side are arranged in a case 14. Each of the gear trains 17, and 18 comprises a plurality of gears 22, 23, 24 and 25 engaged with each other. The case 14 is divided into a plurality of split case bodies 32, and 33. Each of the gear trains 17, and 18 is stored in split case bodies 32, and 33, which are different from each other for each of the gear trans 17, and 18. The split case bodies 32, and 33 can be separably connected to other split case bodies 32, and 33 under a state in which the gear trains 17, and 18 are stored.

Description

  The present invention relates to a transmission mounted on a pump and a pump mounted with the transmission.

  Conventionally, as this type of pump-mounted transmission, for example, as shown in FIG. 16, there is a speed reducer 122 installed in a discharge elbow portion 121 of a vertical pump. The speed reducer 122 includes an input shaft 123, an output-side cylindrical shaft 124, and an intermediate shaft 125 provided between the input shaft 123 and the cylindrical shaft 124. A first gear 126 is provided on the input shaft 123, and a second gear 127 that meshes with the first gear 126 is provided on the intermediate shaft 125. A third gear 128 is provided on the intermediate shaft 125, and a fourth gear 129 that meshes with the third gear 128 is provided on the cylindrical shaft 124. The first and second gears 126 and 127 reduce the first stage, and the third and fourth gears 128 and 129 reduce the second stage.

  A drive shaft 133 of a drive motor 132 is joined to the input shaft 123 via a shaft coupling 131. In addition, a main shaft 134 of a vertical pump is inserted into the cylindrical shaft 124, and the cylindrical shaft 124 and the main shaft 134 are drivingly connected by a shaft coupling 136 at the upper end.

The input shaft 123, the cylindrical shaft 124, the intermediate shaft 125, and the first to fourth gears 126 to 129 are housed in a common case 135.
According to this, the input shaft 123 is rotated by the rotation of the drive shaft 133, and the rotation of the input shaft 123 is decelerated via the first and second gears 126 and 127 and transmitted to the intermediate shaft 125. Are transmitted through the third and fourth gears 128 and 129 to the cylindrical shaft 124 and transmitted from the cylindrical shaft 124 to the main shaft 134. Thereby, the main shaft 134 is rotationally driven.

  The pump-mounted transmission as described above is described in, for example, Patent Document 1 below.

JP 2003-83276 A

  However, in the above conventional type, for example, when the gear ratio of the third and fourth gears 128 and 129 is changed to change the speed reduction ratio of the speed reduction device 122, the entire speed reduction device 122 is case 135 as shown in FIG. Each of them needs to be removed from the discharge elbow portion 121 of the vertical shaft pump and transferred from the pump installation site to a factory or the like, so that there is a problem that a large amount of labor is required for the transfer operation of the entire reduction gear 122.

  It is an object of the present invention to provide a pump-mounted transmission device and a pump that can reduce the labor required for work when changing the transmission gear ratio.

In order to achieve the above object, the first invention is a pump-mounted transmission mounted on a pump casing,
In the case, there are provided a plurality of sets of gear trains for shifting the rotation on the input shaft side and transmitting it to the output shaft side,
Each gear train consists of a plurality of gears meshing with each other,
The case is divided into multiple split case bodies,
Each gear train is housed in a different split case for each gear train,
The split case body is separably joined to another split case body in a state where the gear train is housed.

According to this, by rotating the input shaft, the rotation of the input shaft is shifted through a plurality of sets of gear trains and transmitted to the output shaft.
When changing the gear ratio of one of the multiple gear trains (hereinafter referred to as the target gear train) to change the gear ratio of the transmission, the division case body is removed and the target gear train is removed. What is necessary is just to change the gear ratio of the gear of a gear train.

  And the division | segmentation case body in which the target gear train after changing a gear ratio is accommodated is attached. Since the split case body is smaller than the entire transmission, it is possible to reduce the labor required for work when changing the transmission ratio of the transmission.

In the pump-mounted transmission according to the second aspect of the invention, the plurality of divided case bodies are supported by the pump casing via different support portions provided on the pump casing,
The split case body is detachably joined to the support portion.

  According to this, when the split case body in which the target gear train is stored is removed, the split case body in which the gear train other than the target gear train is stored is supported by the pump casing via the support portion. Therefore, the split case body in which the gear train other than the target gear train is housed does not come off from the pump casing.

In the pump-mounted transmission according to the third aspect of the present invention, a transmission shaft that transmits rotation on the input shaft side to the output shaft side is provided in the case.
The transmission shaft is formed by joining a plurality of separable split shafts.
The split case body is separable from other split case bodies in a state where the transmission shaft is separated into a plurality of split shafts.

According to this, by rotating the input shaft, the rotation of the input shaft is shifted through a plurality of sets of gear trains and transmitted to the output shaft via the transmission shaft.
When changing the gear ratio of the gear of the target gear train and changing the gear ratio of the transmission, the transmission shaft is separated into a plurality of split shafts, and the split case body in which the target gear train is housed is removed. And after changing a gear ratio, the division | segmentation case body in which the target gear train which changed the gear ratio is accommodated may be attached, and a some division | segmentation axis | shaft should be joined.

In the pump-mounted transmission according to the fourth aspect of the present invention, each split shaft is detachably joined via a shaft joint.
According to this, when removing the division | segmentation case body in which the target gear train is accommodated, a transmission shaft can be easily isolate | separated into a some division | segmentation shaft in the location of a shaft coupling. Moreover, when attaching the division | segmentation case body in which the target gear train is accommodated, a transmission shaft can be easily assembled by joining a some division | segmentation axis | shaft with a shaft coupling.

In the pump-mounted transmission according to the fifth invention, the shaft coupling includes a joint member and a position adjustment member,
The joint member joins the split shaft on the input side and the split shaft on the output side of the transmission shaft via the spline fitting portion so as to be integrally rotatable, and is relatively movable in the axial direction.
The position adjusting member determines the position of the joint member in the axial length direction.

  According to this, by rotating the input shaft, the rotation of the input shaft is shifted through a plurality of sets of gear trains and transmitted to the output shaft via the transmission shaft. At this time, the rotation of the split shaft on the input side of the transmission shaft is transmitted to the split shaft on the output side via the spline fitting portion of the joint member.

Further, since the position of the joint member is determined by the position adjusting member, it is possible to prevent the position of the joint member from inadvertently changing in the axial direction along the spline fitting portion.
In the pump-mounted transmission according to the sixth aspect of the present invention, the position adjusting member can adjust the position of the joint member in the axial direction.

  According to this, by adjusting the position of the joint member in the axial length direction, a spline fitting range between the joint member and the input-side split shaft and a spline fitting range between the joint member and the output-side split shaft are obtained. And can be adjusted easily.

The pump-mounted transmission in the seventh invention is a pump-mounted transmission mounted on a pump casing,
In the case, there is provided a gear train for shifting the rotation on the input shaft side and transmitting it to the output shaft side,
The gear train consists of a plurality of gears meshing with each other,
The case is divided into multiple split case bodies,
Each gear meshing with each other in at least one set of gear trains is housed in different split cases.
The split case body is separably joined to another split case body in a state where the gear is housed.

According to this, by rotating the input shaft, the rotation of the input shaft is shifted through the gear train and transmitted to the output shaft.
When changing one of the plurality of gears (hereinafter referred to as a target gear) to change the transmission gear ratio, the division case body in which the target gear is stored is removed, It is only necessary to replace the gear with another gear.

  Then, the split case body in which the replaced gear is stored is attached, and the replaced gear is engaged with the other gear. Since the split case body is smaller than the entire transmission, it is possible to reduce the labor required for work when changing the transmission ratio of the transmission.

  The eighth invention is a pump characterized in that the pump-mounted transmission device according to any one of the first to seventh inventions is provided.

  As described above, according to the present invention, it is possible to reduce the labor required for work when changing the gear ratio.

It is sectional drawing of the reduction gear mounted in the pump in the 1st Embodiment of this invention. It is a XX arrow line view in FIG. It is a YY arrow line view in FIG. It is a ZZ arrow line view in FIG. It is sectional drawing when a 2nd division | segmentation case body is removed from the speed reducer. It is sectional drawing of the shaft coupling of a reduction gear device same as the above. It is sectional drawing of the single item of the coupling member of the shaft coupling of a reduction gear. It is sectional drawing of the single item of the position adjustment member of the shaft coupling of a reduction gear device similarly. It is sectional drawing of the shaft coupling of a reduction gear, and shows the state which lowered | hung the shaft coupling and cancel | released joining of split shafts. It is sectional drawing of the reduction gear mounted in the pump in the 2nd Embodiment of this invention. It is sectional drawing when a 2nd division | segmentation case body is removed from the speed reducer. It is sectional drawing when the 2nd and 3rd division | segmentation case body is integrally removed from the speed reducer. It is a partially expanded sectional view of the reduction gear device in the 3rd Embodiment of this invention. It is sectional drawing when a 2nd division | segmentation case body is removed from the speed reducer. It is sectional drawing of the reduction gear device in the 4th Embodiment of this invention. It is sectional drawing of the reduction gear mounted in the conventional pump.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
As shown in FIG. 1, reference numeral 1 denotes a vertical shaft pump. The pump casing 2 has a suction casing (not shown) at the lower end and an elbow-shaped discharge casing 4 at the top. A suction port (not shown) is formed in the suction casing, and a discharge port 4 a is formed in the discharge casing 4. A main shaft 6 is inserted into the pump casing 2, and an impeller (not shown) is provided at the lower end portion of the main shaft 6, and an upper portion of the main shaft 6 passes through the discharge casing 4 from the pump casing 2 and moves upward. It protrudes.

  A prime mover 9 (an example of a drive device) that rotationally drives the main shaft 6 is installed on the upper side of the pump casing 2. The prime mover 9 is composed of an engine or the like, and between the prime mover 9 and the main shaft 6, a pump-mounted reduction device 11 (transmission device) that reduces the rotation of the prime mover 9 (an example of a shift) and transmits it to the main shaft 6. And a clutch device 12 that connects and separates the prime mover 9 and the speed reducer 11. The prime mover 9 has a drive shaft 10, and a relay shaft 13 is connected between the drive shaft 10 and the clutch device 12.

One end of the relay shaft 13 is detachably joined to the drive shaft 10 via a shaft joint 8 such as a flange joint. The other end of the relay shaft 13 is joined to the clutch device 12.
The speed reducer 11 is mounted on the discharge casing 4, and includes a case 14, an input shaft 15, an output shaft 16, and a plurality of sets (two sets in FIG. 1) of gear trains 17 that reduce the rotation of the input shaft 15. , 18 and a transmission shaft 19 that rotates together with the gear trains 17, 18 and transmits the rotation of the input shaft 15 to the output shaft 16. The input shaft 15 and the transmission shaft 19 are disposed orthogonally, the transmission shaft 19 and the output shaft 16 are parallel to each other, and the shaft is disposed in the vertical (up and down) direction. The main shaft 6 is the output shaft 16. Is disposed on the same axis.

  The first gear train 17 includes a pair (a plurality of examples) of bevel gears 22 and 23 that mesh with each other, and the second gear train 18 includes a pair (a plurality of examples) of spur gears 24 and 25 that mesh with each other. Become. The transmission shaft 19 is housed in the case 14 so that the shaft is in the vertical (up and down) direction, and is rotatably supported by a plurality of upper and lower bearings 27 to 30.

  One bevel gear 22 of the first gear train 17 is provided on the input shaft 15, and the other bevel gear 23 is provided below the transmission shaft 19. Further, one spur gear 24 of the second gear train 18 is provided on the upper portion of the transmission shaft 19, and the other spur gear 25 is provided on the output shaft 16.

  The case 14 is divided into a plurality (two in the upper and lower parts in FIG. 1) divided case bodies 32 and 33. Among these, as shown in FIGS. 1 to 3, the lower first divided case body 32 is detachably attached to a box-shaped case main body portion 32a having an open upper end portion and an upper end of the case main body portion 32a. The upper cover part 32b provided and the lower flange 32c provided in the outer side of the lower end part of the case main body part 32a are provided. A work opening 32d is formed on the side surface of the case main body 32a.

  The first divided case body 32 is supported by the discharge casing 4 via the first support portion 34. The first support portion 34 is provided outside the discharge casing 4, and the lower flange 32 c of the first split case body 32 is joined to the first support portion 34 by a plurality of bolts 35 (an example of a connecting member). It is fixed. By removing these bolts 35, the first divided case body 32 can be separated from the first support portion 34.

  As shown in FIGS. 1 and 4, the upper second divided case body 33 is provided above the first divided case body 32, and has a box-like case main body with its upper and lower ends open. 33a, an upper lid portion 33b that is detachably provided at the upper end of the case body portion 33a, and a lower flange 33c that is provided at the outer periphery of the lower end portion of the case body portion 33a. A plurality of work openings 33d and 33e are formed on the side surface of the case body 33a.

  The second divided case body 33 is supported by the discharge casing 4 via the second support portion 37. The second support portion 37 is provided outside the discharge casing 4, and the lower flange 33 c of the second split case body 33 is joined to the second support portion 37 by a plurality of bolts 38 (an example of a connecting member). It is fixed.

  The upper lid portion 32b of the first divided case body 32 and the lower flange 33c of the second divided case body 33 are joined by a plurality of bolts 38 (an example of a connecting member). As shown in FIG. 5, the second split case body 33 can be separated from both the second support portion 37 and the first split case body 32 by removing these bolts 38.

  As shown in FIG. 1, the first gear train 17 is housed in the first split case body 32, and the second gear train 18 is housed in the second split case body 33. The input shaft 15 is detachably connected to the relay shaft 13 via the clutch device 12, and is rotatably supported by the first split case body 32 via the bearing 40. Note that one end portion of the input shaft 15 is joined to the clutch device 12, and the other end portion of the input shaft 15 enters the first split case body 32. The output shaft 16 is housed in the second divided case body 33 and is rotatably supported via a plurality of upper and lower bearings 41.

  The transmission shaft 19 is formed by joining a plurality of separable split shafts 19a and 19b (upper and lower two in FIG. 1) and first and second split case bodies 32 and 33 (a plurality of split case bodies). For example). Of these, most of the first split shaft 19a (an example of the input-side split shaft) is housed in the first split case body 32, and the upper end portion of the first split shaft 19a is the upper lid portion 32b of the first split case body 32. And penetrates into the second divided case body 33. The second split shaft 19 b (an example of the output-side split shaft) is housed in the second split case body 33.

  As shown in FIGS. 1 and 6, splines are formed on the outer periphery of the upper end portion of the first split shaft 19a and the outer periphery of the lower end portion of the second split shaft 19b. Further, a protrusion 36 is provided at the upper end of the first split shaft 19a, and a recess 39 is formed at the lower end of the second split shaft 19b. The protrusion 36 can be inserted into and removed from the recess 39 in the axial direction A (vertical direction). A male screw portion 42 is formed on the outer periphery of the first split shaft 19a and below the spline.

  The first split shaft 19a and the second split shaft 19b are detachably joined via the shaft joint 43 in a state where the protrusion 36 is inserted into the recess 39. The shaft joint 43 has an upper joint member 44 and a lower position adjustment member 45. The upper end portion of the first split shaft 19 a penetrates the position adjusting member 45 and is inserted into the joint member 44 from below. The lower end portion of the second split shaft 19b is inserted into the joint member 44 from above.

  The joint member 44 joins the first split shaft 19a and the second split shaft 19b via the spline fitting portion 47 so as to be integrally rotatable, and is relatively movable in the axial direction A. As shown in FIG. 7, the joint member 44 is a cylindrical member and has a spline on the inner periphery. Further, the joint member 44 is formed with a plurality of bolt insertion holes 48 penetrating through both end faces in the axial length direction A at a plurality of locations in the circumferential direction.

  As shown in FIG. 6, the position adjustment member 45 determines the position of the joint member 44 in the axial length direction A and is adjustable. As shown in FIG. 8, the position adjustment member 45 is a cylindrical member, and has an inner flange portion 50 that protrudes radially inward on the inner peripheral upper portion, and a female screw portion 51 on the inner peripheral lower portion. have. A plurality of bolt mounting holes 52 are formed at a plurality of locations in the circumferential direction on the upper end surface of the position adjusting member 45. As shown in FIG. 6, the female screw portion 51 of the position adjusting member 45 is screwed into the male screw portion 42 of the first split shaft 19 a, whereby the position of the position adjusting member 45 is the first split in the axial length direction A. It is fixed to the shaft 19a.

  In the present embodiment, as shown in FIG. 8, the position adjusting member 45 has the inner flange portion 50 over the entire circumference. However, as shown in FIG. 9, the position adjusting member 45 has the first division. The inner flange 50 may be formed not at the entire circumference but at a plurality of locations in the circumferential direction, as long as the function of locking to the male threaded portion 42 of the shaft 19a and not falling is obtained. Any shape may be used as long as it can be locked. Alternatively, the inner collar part 50 may be formed as a separate member from the position adjusting member 45, and when there is no risk of the position adjusting member 45 falling, the inner collar part 50 is dropped without being attached to the position adjusting member 45. When there is a concern, the inner collar portion 50 may be attached to the position adjusting member 45.

  A plurality of bolts 53 (an example of a connecting member) are inserted into the bolt insertion holes 48 of the joint member 44 and screwed into the bolt mounting holes 52 of the position adjustment member 45. As a result, the joint member 44 and the position adjusting member 45 are connected via the bolt 53, and the spline of the first split shaft 19a and the lower portion of the spline of the joint member 44 are fitted together and the second split shaft 19b is connected. The spline and the upper part of the spline of the joint member 44 are fitted together to form a spline fitting portion 47, and the joint member 44 is joined to the split shafts 19a and 19b via the spline fitting portion 47.

  As described above, the joint member 44 and the position adjustment member 45 are connected by the bolt 53, whereby the position adjustment member 45 is restricted from rotating at the female screw portion 51 and can fix the position of the joint member 44. . The rotation of the first split shaft 19a is transmitted to the second split shaft 19b by the spline fitting portion 47, and the bolt 53 does not contribute to the transmission of rotation. For this reason, the size of the bolt 53 can be reduced to achieve a reduction in size and weight.

As shown in FIG. 1, the main shaft 6 and the output shaft 16 are detachably joined via a shaft coupling 60. The shaft coupling 60 has the same configuration as the shaft coupling 43, and a detailed description thereof will be omitted.
Hereinafter, the operation of the above configuration will be described.

  When operating the vertical shaft pump 1, as shown in FIG. 1, the prime mover 9 is driven, and the relay shaft 13 and the input shaft 15 of the speed reducer 11 are connected via the clutch device 12. Thereby, the rotation of the drive shaft 10 is transmitted to the input shaft 15 through the shaft coupling 8, the relay shaft 13, and the clutch device 12, and the input shaft 15 rotates. The rotation of the input shaft 15 is decelerated by the first gear train 17 and transmitted to the transmission shaft 19, decelerated by the second gear train 18 from the transmission shaft 19, and transmitted to the output shaft 16. It is transmitted to the main shaft 6 via the joint 60. Thereby, the impeller rotates together with the main shaft 6, and water is sucked into the pump casing 2 from the suction port and discharged from the discharge port 4a.

  At this time, as shown in FIG. 6, the rotation of the first split shaft 19a in the transmission shaft 19 is transmitted to the second split shaft 19b through the spline fitting portion 47 of the joint member 44 of the shaft joint 43. The Further, the position of the joint member 44 is determined by the position adjusting member 45 in the axial length direction A. For this reason, it is possible to prevent the position of the joint member 44 from inadvertently changing in the axial direction A along the spline fitting portion 47.

  Further, the coupling member 44 and the position adjusting member 45 are connected by the bolt 53, so that the position adjusting member 45 is restricted from rotating at the female screw portion 51, and the position of the coupling member 44 can be reliably fixed. .

  Of the first and second gear trains 17, 18, for example, the gear ratio of the spur gears 24, 25 of the second gear train 18 (an example of the target gear train) is changed to change the reduction gear ratio (speed change) of the reduction gear 11. In the case of changing the ratio), the prime mover 9 is stopped and the operation of the vertical shaft pump 1 is stopped. As shown in FIG. 9, first, the bolt 53 of the shaft coupling 43 is removed, and the position adjusting member 45 is moved in one direction. By rotating, the female screw portion 51 of the position adjusting member 45 is sent to the male screw portion 42 of the first split shaft 19a, and the position adjusting member 45 moves downward. In this way, the female screw part 51 is detached below the male screw part 42. The position adjusting member 45 is lowered along the first split shaft 19a, and the lowering of the position adjusting member 45 is restricted by the inner flange portion 50 being engaged with the male screw portion 42 from above.

  Thereafter, the joint member 44 is lowered along the spline of the spline fitting portion 47, the spline of the joint member 44 is detached from the spline of the second split shaft 19b, and the joint member 44 is moved downward from the second split shaft 19b. By removing, the transmission shaft 19 can be easily separated into the first split shaft 19a and the second split shaft 19b at the shaft coupling 43. Such an operation can be performed by an operator through one of the operation openings 33 d of the second divided case body 33.

  Further, in the same manner as described above, the joint member 44 and the position adjusting member 45 of the shaft joint 60 are lowered, and the output shaft 16 and the main shaft 6 are separated. This work can be performed by the worker through the other work opening 33e of the second divided case body 33.

  After that, as shown in FIG. 5, the first split case body 32 in which the first gear train 17 (an example of a gear train other than the target gear train) is housed is attached and the second gear train 17 is attached. The second divided case body 33 in which the gear train 18 is accommodated is removed. That is, by removing the bolt 38, the connection between the second divided case body 33 and the second support portion 37 and the connection between the first divided case body 32 and the second divided case body 33 are released. The second split case body 33 can be removed upward while the second gear train 18 is housed.

At this time, since the first divided case body 32 is supported by the discharge casing 4 via the first support portion 34, the first divided case body 32 is not detached from the discharge casing 4.
The second split case body 33 removed in this way is transferred from the pump installation site to a factory or the like, and either one or both of the spur gears 24, 25 of the second gear train 18 are changed to another spur gears 24, 25. Change to change gear ratio.

  And the 2nd division | segmentation case body 33 in which the 2nd gear train 18 after changing gear ratio is accommodated is transferred to a pump installation site from a factory, and the 2nd division | segmentation case body 33 is attached. That is, as shown in FIG. 1, by attaching the bolt 38, the second divided case body 33 and the second support portion 37 are coupled, and the first divided case body 32 and the second divided case body. 33 is connected.

  Thereafter, as shown in FIG. 6, the joint member 44 of the shaft joint 43 is lifted, and the spline of the joint member 44 is fitted to the spline of the first split shaft 19a. Fit to spline. Further, the position adjusting member 45 is lifted and rotated to screw the female screw portion 51 of the position adjusting member 45 into the male screw portion 42 of the first split shaft 19a. As a result, the position adjusting member 45 is attached to the first split shaft 19a via the male screw portion 42 and the female screw portion 51, and the joint member 44 is supported by the position adjusting member 45 from below, and the mounting position thereof is the axis. Defined in the long direction A.

  Further, by rotating the position adjusting member 45, the mounting position of the position adjusting member 45 can be changed in the axial length direction A, so that the position of the joint member 44 can be adjusted in the axial length direction A. The fitting range of the spline between the joint member 44 and the first split shaft 19a and the fitting range of the spline between the joint member 44 and the second split shaft 19b can be easily adjusted. Therefore, even if an error occurs in the distance between the shaft ends of the split shafts 19a and 19b due to the production and assembly of the split shafts 19a and 19b and the split case bodies 32 and 33, the transmission shafts absorb the errors. 19 can be assembled.

  Further, by changing the reduction ratio, the rotation transmission force from the first split shaft 19a to the second split shaft 19b may change, and the spline fitting range may need to be changed. In this case, the splines of the split shafts 19a and 19b have a sufficient length, but the splines of the joint member 44 may be insufficient in length. In such a case, the splines have a sufficient length. It is also possible to replace the joint member 44 to cope with it.

  Thereafter, the bolt 53 is attached and the joint member 44 and the position adjusting member 45 are connected to assemble the shaft joint 43, and the second split shaft 19 b is connected to the first split shaft 19 a via the shaft joint 43. Since they are joined, the transmission shaft 19 can be easily assembled. Such an operation can be performed by an operator through one of the operation openings 33 d of the second divided case body 33.

  Further, in the same manner as described above, the shaft coupling 60 is assembled, and the output shaft 16 is joined to the main shaft 6 via the shaft coupling 60. This work can be performed by the worker through the other work opening 33e of the second divided case body 33.

  As described above, when the gear ratio of the second gear train 18 is changed to change the reduction gear ratio of the reduction gear 11, the first split case body 32 in which the first gear train 17 is housed is attached. In this state, the second split case body 33 in which the second gear train 18 is accommodated is removed, and only the second split case body 33 is transferred between the pump installation site and the factory. Thereby, since the 2nd division | segmentation case body 33 is small compared with the speed reducer 11 whole, the effort and time which are required for the operation | work of transfer and replacement | exchange at the time of changing the reduction ratio of the speed reducer 11 can be reduced. .

  When the gear ratio of the bevel gears 22 and 23 of the first gear train 17 is changed to change the reduction ratio of the reduction gear 11, the second procedure is performed once in the same procedure as shown in FIG. The split case body 33 is removed, and the drive shaft 10 and the relay shaft 13 are separated from the shaft coupling 8. In this state, the first split case body in which the first gear train 17 is accommodated by removing the bolt 35 and releasing the connection between the first split case body 32 and the first support portion 34. 32 can be removed together with the clutch device 12.

  The first divided case body 32 removed in this way is transferred from the pump installation site to a factory or the like, and either one or both of the bevel gears 22 and 23 of the first gear train 17 is changed to another bevel gears 22 and 23. Change to change gear ratio.

  And the 1st division | segmentation case body 32 in which the 1st gear train 17 after changing gear ratio is accommodated is transferred to a pump installation site from a factory, and the 1st division | segmentation case body 32 is attached. That is, the bolt 35 is attached, the first divided case body 32 and the first support portion 34 are connected, and then the second divided case body 33 is attached in the same procedure as described above, and the shaft coupling is further connected. The drive shaft 10 and the relay shaft 13 are joined via 8.

  In this way, only the first divided case body 32 in which the first gear train 17 is housed may be transferred between the pump installation site and the factory, and the first divided case body 32 is disposed throughout the speed reduction device 11. Compared to the small size, it is possible to reduce the labor and time required for transfer and replacement work when changing the reduction ratio of the reduction gear 11.

  That is, when changing the gear ratio of the transmission device by changing the gear ratio of the gear of the target gear train among the plurality of sets of gear trains, the split case body in which the gear train other than the target gear train is accommodated. Remove the split case body in which the target gear train is housed while still attached to the pump casing, transfer the removed split case body from the pump installation site to the factory, etc., and change the gear ratio of the gear of the target gear train. Just change.

  And the division | segmentation case body in which the target gear train after changing gear ratio is accommodated is transferred to a pump installation site from a factory, and this division | segmentation case body is attached to the division | segmentation case body which remained in the pump casing. Since the split case body is smaller than the entire transmission, it is possible to reduce the labor required for work when changing the transmission ratio of the transmission.

  Furthermore, even when repairing the entire transmission, by dividing the case of the transmission into a plurality of divided case bodies, it is possible to reduce the size of vehicles, cranes, etc. used for transfer, and transfer work Can be reduced.

(Second Embodiment)
In the first embodiment, as shown in FIG. 1, the case 14 is divided into the first and second divided case bodies 32 and 33. In the second embodiment, the case 14 is shown in FIGS. As shown, the case 14 is divided into three divided into first to third divided case bodies 32, 33, and 63. The third split case body 63 does not store the gear train, and stores the shaft coupling 43. The third divided case body 63 is provided between the lower first divided case body 32 and the upper second divided case body 33. The lower end portion of the third split case body 63 and the upper end portion of the first split case body 32 are joined to each other by a plurality of bolts 64 (connection members) so as to be separable. The upper end portion of the third divided case body 63 and the second divided case body 33 are joined to each other by a plurality of bolts 65 (connecting members) so as to be separable.

Hereinafter, the operation of the above configuration will be described.
When changing the gear ratio of the second gear train 18, as shown in FIG. 11, the transmission shaft 19 is separated into the first split shaft 19a and the second split shaft 19b at the shaft coupling 43, and the shaft The output shaft 16 and the main shaft 6 are separated at the joint 60. Then, the bolt 38 is removed, the connection between the second divided case body 33 and the second support portion 37 is released, the bolt 65 is removed, and the second divided case body 33 and the third divided case body 63 are removed. Disconnect from the link. Thereby, the 2nd division | segmentation case body 33 can be removed upwards in the state which accommodated the 2nd gear train 18. FIG.

  Thereafter, as shown in FIG. 10, the second split case body 33 in which the second gear train 18 with the changed gear ratio is accommodated is connected to the second support portion 37 by the bolt 38, and further, the bolt 65 To the third divided case body 63. Further, the transmission shaft 19 is assembled by joining the first split shaft 19 a and the second split shaft 19 b by the shaft joint 43, and the output shaft 16 and the main shaft 6 are joined by the shaft joint 60.

  As described above, when changing the gear ratio of the second gear train 18, only the second divided case body 33 is removed and transferred while the first and third divided case bodies 32 and 63 remain attached. do it. Thereby, since the 2nd division | segmentation case body 33 is small compared with the speed reducer 11 whole, the effort and time which are required for the operation | work of transfer and replacement | exchange at the time of changing the reduction ratio of the speed reducer 11 can be reduced. .

  Further, when changing the gear ratio of the first gear train 17, the drive shaft 10 and the relay shaft 13 are separated at the position of the shaft joint 8, and the transmission shaft 19 is connected to the first split shaft at the position of the shaft joint 43. 19a and the second split shaft 19b are separated, and the output shaft 16 and the main shaft 6 are separated at the shaft coupling 60. Then, the bolt 38 is removed, the connection between the second divided case body 33 and the second support portion 37 is released, the bolt 64 is removed, and the first divided case body 32 and the third divided case body 63 are removed. Disconnect from the link.

  In this state, as shown in FIG. 12, the third divided case body 63 is once removed from the first divided case body 32 together with the second divided case body 33. Then, by removing the bolt 35 and releasing the connection between the first divided case body 32 and the first support portion 34, the first divided case body 32 in which the first gear train 17 is accommodated is removed. It can be removed together with the clutch device 12.

  Thereafter, as shown in FIG. 10, the first divided case body 32 in which the first gear train 17 with the changed gear ratio is accommodated is connected to the first support portion 34 by the bolt 35, and the second divided case body 32 is connected. The case body 33 is connected to the second support portion 37 by a bolt 38, and the third divided case body 63 is connected to the first divided case body 32 by a bolt 64.

  Furthermore, the drive shaft 10 and the relay shaft 13 are joined via the shaft joint 8, the first split shaft 19 a and the second split shaft 19 b are joined via the shaft joint 43, and the shaft joint 60 is used. The output shaft 16 and the main shaft 6 are joined.

  Thus, it is sufficient to transfer only the first divided case body 32 in which the first gear train 17 is housed. Since the first divided case body 32 is smaller than the entire speed reducer 11, the speed reducer is reduced. Therefore, it is possible to reduce the labor and time required for transfer and replacement work when changing the reduction ratio of 11.

In addition, as a modification of the second embodiment, a configuration in which the third divided case body 63 is omitted is also possible.
(Third embodiment)
In the first embodiment, as shown in FIG. 1, the transmission shaft 19 is divided into first and second split shafts 19a and 19b, and both the split shafts 19a and 19b are joined together by a shaft joint 43. However, in the third embodiment described below, the transmission shaft 19 is not divided and the shaft coupling 43 is not used.

  That is, as shown in FIG. 13, one spur gear 24 of the second gear train 18 is integrally attached to the cylindrical shaft body 67, and the upper end portion of the transmission shaft 19 is inserted into the cylindrical shaft body 67 from below. ing. The cylindrical shaft body 67 and the upper end portion of the transmission shaft 19 are interlocked and connected in the circumferential direction via a spline fitting portion 68 and are relatively movable in the axial length direction A.

Hereinafter, the operation of the above configuration will be described.
When operating the vertical shaft pump 1, the rotation of the transmission shaft 19 is transmitted to one spur gear 24 via the spline fitting portion 68.

  When the gear ratio of the spur gears 24 and 25 of the second gear train 18 is changed to change the reduction gear ratio of the reduction gear 11, the bolt 38 is removed as shown in FIG. 33 is pulled up, and the cylindrical shaft body 67 is moved upward along the spline of the spline fitting portion 68. As a result, the cylindrical shaft body 67 can be removed above the transmission shaft 19, so that the second split case body is accommodated in a state in which both spur gears 24 and 25 are housed in the second split case body 33. 33 can be removed upward.

  In the third embodiment, the cylindrical shaft body 67 and the transmission shaft 19 are connected so as to be integrally rotatable via a spline fitting portion 68. However, the cylindrical shaft body 67 and the transmission shaft 19 are connected to each other. Can be connected using a key, or can be connected using the shaft coupling 136 shown in FIG. 16, as long as the function of allowing relative movement in the axial direction A is obtained.

(Fourth embodiment)
In the first embodiment, as shown in FIG. 1, the case 14 has a structure that can be divided into two vertically divided case bodies 32 and 33. However, in the fourth embodiment described below, the case 14 is shown in FIG. As shown, the case 14 has a structure that can be divided into two in the left-right direction (the axial center direction of the input shaft 15).

  That is, the case 14 includes divided case bodies 71 and 72 that can be divided into left and right. These divided case bodies 71 and 72 have flange portions 71a and 72a, respectively. By connecting these flange portions 71a and 72a with a plurality of bolts and nuts 73 (connecting members), the divided case bodies 71 and 72a are connected. The cases 14 are assembled by joining the members 72 in a separable manner.

  In one divided case body 71, the first gear train 17, the transmission shaft 19, and one spur gear 24 of the second gear train 18 are accommodated. In the other split case body 72, the other spur gear 25 of the second gear train 18 and the output shaft 16 are housed.

Hereinafter, the operation of the above configuration will be described.
For example, when one spur gear 24 (an example of a target gear) of the second gear train 18 is replaced to change the speed ratio of the reduction gear 11, the drive shaft 10 and the relay shaft 13 are connected from the position of the shaft coupling 8. , The bolt 35 and the bolt and nut 73 are removed, and the other split case body 72 is attached, and one spur gear 24 is housed as shown by the phantom line in FIG. The split case body 71 is removed upward, the one split case body 71 removed is transferred from the pump installation site to a factory or the like, and one spur gear 24 is replaced with another gear.

  Thereafter, the one split case body 71 in which the replaced spur gear 24 is housed is transferred from the factory to the pump installation site, the bolt 35, the bolt and the nut 73 are attached, and the one split case body 71 is attached to the other. The split case body 72 and the first support portion 34 are joined, and the replaced one spur gear 24 is engaged with the other spur gear 25, and the drive shaft 10 and the relay shaft 13 are joined via the shaft coupling 8. To do. Thereby, since one division | segmentation case body 71 is small compared with the speed reducer 11 whole, the effort and time required for the operation | work of a transfer and replacement | exchange at the time of changing the reduction ratio of the speed reducer 11 can be reduced.

  In the above example, one split case body 71 is removed and one spur gear 24 is replaced. However, the gear ratio of the speed reducer 11 is changed by replacing the bevel gears 22 and 23 of the first gear train 17. The same can be done in the same way.

  When the other spur gear 25 of the second gear train 18 is replaced to change the speed ratio of the speed reducer 11, the joint member 44 and the position adjustment member 45 of the shaft joint 60 are lowered to output the output shaft. 16 and the main shaft 6 are separated, the bolt 38 and the bolts and nuts 73 are removed, and the other split case body 72 in which the other spur gear 25 is accommodated is left with one split case body 71 attached. Remove it. Also in this case, similarly, since the other divided case body 72 is smaller than the entire speed reduction device 11, the labor and time required for the transfer and replacement work when changing the speed reduction ratio of the speed reduction device 11 are reduced. be able to.

  In the first to third embodiments, the case 14 can be divided in a state where the gear trains 17 and 18 are individually stored in the divided case bodies 32 and 33. Compared to the divided configuration of the case 14 described in the embodiment, there is an advantage that when the case 14 is divided into a plurality of divided case bodies 32 and 33, foreign matters such as dust are less likely to enter the gear trains 17 and 18. is there.

  In the first embodiment, as shown in FIG. 1, the first and second split shafts 19 a and 19 b are joined by the shaft joint 43, but they are joined by using a spacer coupling instead of the shaft joint 43. May be. In this case, what is necessary is just to join the 1st and 2nd division | segmentation axis | shafts 19a and 19b with a spacer coupling in the location which faces the junction part of the 1st and 2nd division | segmentation case bodies 32 and 33. FIG. Accordingly, when the spacer coupling is removed and the first split shaft 19a and the second split shaft 19b are separated, the spacer coupling is provided between the first split shaft 19a and the second split shaft 19b. Therefore, the first divided case body 32 can be removed with the second divided case body 33 attached.

  In each of the above-described embodiments, the speed reducer 11 that decelerates the rotation of the prime mover 9 and transmits it to the main shaft 6 is described as an example of the transmission. However, the speed increase that increases the rotation of the prime mover 9 and transmits it to the main shaft 6. It may be a device.

In each of the above-described embodiments, the speed reduction device 11 is mounted on the vertical shaft pump 1, but a pump other than the vertical shaft pump 1, for example, a horizontal shaft pump or the like may be used.
In each of the embodiments described above, two sets of gear trains 17 and 18 are provided, but one set of gear trains or a plurality of sets of three or more sets may be provided.

In each of the above embodiments, the transmission shaft 19 is divided into the first and second divided shafts 19a and 19b. However, the transmission shaft 19 may be divided into three or more and a plurality of shaft couplings 43 may be provided according to the number of divisions. .
In each of the above embodiments, the case 14 of the speed reducer 11 is divided into two or three divided case bodies 32, 33, 63, 71, 72, but is divided into four or more divided case bodies. May be.

In each of the embodiments described above, the bevel gears 22 and 23 and the spur gears 24 and 25 are used as an example of the gear, but other types of gears may be used.
In each of the above embodiments, the first gear train 17 is composed of the two bevel gears 22 and 23, but may be composed of a plurality of three or more gears. Similarly, the second gear train 18 is composed of two gears 24 and 25, but may be composed of three or more spur gears and bevel gears.

  In each of the above embodiments, the divided case bodies 32, 33, 71, and 72 are made in cans, but may be castings or the like, and the material thereof is not particularly limited, and may be steel or other metals or It may be other than.

  In each of the above embodiments, the gear ratio is changed by transferring from the pump installation site to a factory or the like, but it is also possible to change the gear ratio by exchanging gears at the pump installation site. In addition, in a factory or the like, a gear train whose gear ratio has been changed in advance is stored and prepared in a split case body, and the work time is further reduced by transferring the split case body from the factory or the like to the pump installation site. And save time.

  In addition, even if the operating conditions and points of use of the pump are changed and the existing pump cannot be used, it may be requested to use the existing pump without replacing the pump due to a request for cost reduction. In this case, if the pump has the speed reducer of the present invention, the cost can be reduced by replacing a part of the speed reducer.

  Also, due to reasons such as the life of the prime mover (engine, etc.), when the prime mover is updated, the rotational speed may be increased to reduce the size and weight. Need to change. If it is a pump provided with the reduction gear of this invention, it can respond easily.

1 Vertical shaft pump 2 Pump casing 11 Reduction gear (transmission)
14 Case 15 Input shaft 16 Output shaft 17, 18 Gear train 19 Transmission shaft 19a First split shaft (input-side split shaft)
19b Second split axis (output-side split axis)
22, 23 Bevel gears 24, 25 Spur gears 32, 33, 71, 72 Split case bodies 34, 37 Support portion 43 Shaft joint 44 Joint member 45 Position adjustment member 47 Spline fitting portion A Axial length direction

Claims (8)

A pump-mounted transmission mounted on a pump casing,
In the case, there are provided a plurality of sets of gear trains for shifting the rotation on the input shaft side and transmitting it to the output shaft side,
Each gear train consists of a plurality of gears meshing with each other,
The case is divided into multiple split case bodies,
Each gear train is housed in a different split case for each gear train,
The pump-equipped transmission, wherein the split case body is separably joined to another split case body in a state in which the gear train is housed. The plurality of divided case bodies are supported by the pump casing via different support portions provided in the pump casing,
The pump-equipped transmission according to claim 1, wherein the divided case body is detachably joined to the support portion. A transmission shaft that transmits rotation on the input shaft side to the output shaft side is provided in the case,
The transmission shaft is formed by joining a plurality of separable split shafts.
3. The pump-mounted transmission according to claim 1, wherein the split case body is separable from other split case bodies in a state where the transmission shaft is separated into a plurality of split shafts. 4. The pump-mounted transmission according to claim 3, wherein each of the divided shafts is detachably joined via a shaft joint. The shaft coupling has a coupling member and a position adjustment member,
The joint member joins the split shaft on the input side and the split shaft on the output side of the transmission shaft via the spline fitting portion so as to be integrally rotatable, and is relatively movable in the axial direction.
5. The pump-mounted transmission according to claim 4, wherein the position adjusting member determines the position of the joint member in the axial direction. 6. The pump-mounted transmission according to claim 5, wherein the position adjusting member is capable of adjusting the position of the joint member in the axial length direction. A pump-mounted transmission mounted on a pump casing,
In the case, there is provided a gear train for shifting the rotation on the input shaft side and transmitting it to the output shaft side,
The gear train consists of a plurality of gears meshing with each other,
The case is divided into multiple split case bodies,
Each gear meshing with each other in at least one set of gear trains is housed in different split cases.
The split-case body is a pump-equipped transmission, wherein the split case body is separably joined to another split case body in a state in which a gear is accommodated. A pump, characterized in that the pump-mounted transmission according to any one of claims 1 to 7 is provided.

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