KR101348710B1 - Apparatus for injecting of medicine - Google Patents

Abstract

The present invention relates to a fixed-quantity drug injection device, the main pump 20 is connected to the pipe 10 for fire fighting or water treatment, and the inlet, outlet 21, 22 and the rotational force generating unit 23, and Auxiliary pump 30 provided with a pumping unit 31 for generating a predetermined pumping force by receiving the rotational force of the main pump 20 and the transmission 40 disposed between the main pump 20 and the auxiliary pump 30 It is configured to include.
Therefore, the power generation using the pipe water flow of the water treatment basically eliminates the need for a separate power source, thereby reducing the cost of the device, and consequently, improving the competitiveness of the device. The transmission between the pumps allows the injection of chemicals to be always injected at the correct rate through the constant pumping force of the auxiliary pump, regardless of the flow rate of the pipe flow, resulting in improved workability and work efficiency. In addition, by applying a lobe (vane) rotor having excellent adhesion to the double-axis fixed rotation as the rotational force generating portion of the main pump, the injection of the drug while enabling quantitative flow by minimizing the gap This can be done precisely so that trust in the device To obtain the effects such as being able to impart improved.

Description

Apparatus for injecting of medicine

The present invention relates to a quantitative drug injection device, and more particularly, a main pump connected to a pipe for fire fighting or water treatment and the like to obtain a rotational force by the flow of water, and receiving a rotational force of the main pump, By providing an auxiliary pump for generating a pumping force and a transmission disposed between the main pump and the auxiliary pump to shift the rotational power of the main pump to the auxiliary pump, a separate power source is basically generated by the generation of power using the pipe flow of water treatment In addition, it is not necessary, and the transmission between the main pump and the auxiliary pump can be injected into the fixed amount of the drug through the constant pumping force of the auxiliary pump irrespective of the flow rate of the pipe water flow, will be.

In general, the drug injection device refers to a device for injecting drugs such as chemicals required for the fire water or water treatment water flowing through the pipe for firefighting or water treatment to improve the firefighting performance or water treatment efficiency.

Since the medicine injection device must inject the medicine while the fire water or the water treatment water flows along the pipe in a firefighting or water treatment operation as described above, the medicine injection device is directly connected to the pipe through which the fire water or the water treatment water flows to inject the medicine. The device is configured.

As an example, if the drug injection device of the prior art is outlined, a medicine supply pipe is provided which is connected to the fire fighting or water treatment pipe and connected to supply the medicine into the pipe, and supplies the medicine to supply the external medicine through the medicine supply pipe. It may be configured to include a part.

In addition, the drug supply unit should be provided with a high-pressure pump to be able to inject the drug at a higher pressure than the water flow of the pipe, and should also be provided with a separate auxiliary pump for pumping the drug from the external drug tank. .

Looking at the drug injection process through the drug injection device of the prior art having such a configuration, first the first step of pumping the drug from the drug tank through the auxiliary pump and then the high-pressure injection of the pumped drug back into the stream of water through the high pressure pump Drug injection operation is performed through.

In addition, in another conventional technology, there is an example of applying a pump to obtain rotational force by eccentric rotation as a vane structure using a single shaft.

However, since the conventional quantitative drug injection device requires a separate power source in order to pump the drug from the drug tank or to inject the drug into the pipe at a high pressure, there is a problem in the cost burden due to the power source.

In addition, the vane-type structure using a single shaft is a eccentric rotation in the case of the pump to obtain a rotational force by the eccentric rotation, because of the eccentric rotation method, there was a problem that the high speed rotation and noise and vibration is also severe.

In addition, since there is no separate means for countermeasure to cope with changes in the water flow, it is difficult to continuously inject the drug at a quantitative rate, resulting in poor workability, such as fire fighting and water treatment, which leads to a decrease in reliability of the device. There was a problem such as.

The present invention has been made to solve this problem, the main pump having a lobe-type rotor consisting of two shafts connected to the pipe for firefighting or water treatment, so as to obtain a rotational force by the water flow, and the main pump By using the auxiliary pump for receiving the rotational force of the pump to generate a predetermined pumping force and a transmission disposed between the main pump and the auxiliary pump to shift the rotational power of the main pump to the auxiliary pump, basically using the pipe flow of water treatment The power generation eliminates the need for a separate power source, resulting in cost savings due to semi-permanent energy saving of the device, resulting in improved competitiveness of the device, as well as high speed rotation without eccentricity by two shafts. Quantitatives to minimize noise and vibration The purpose is to provide an injection device.

In addition, by increasing the rotation rate of the auxiliary pump by the transmission between the main pump and the auxiliary pump so that the mixing ratio can be adjusted even at the minimum flow rate, the injection rate of the drug is always corrected through the constant pumping force of the auxiliary pump regardless of the flow rate of the pipe. Another purpose is to provide a quantitative drug injection device that can be injected into the consequently resulting in improved workability and efficiency, leading to improved reliability of the device as a whole.

In addition, by applying a lobe (vane) rotor having excellent adhesion to the double-axis fixed rotation as the rotational force generating portion of the main pump, it is possible to precisely inject the drug while allowing quantitative flow by minimizing the gap. It is another object to provide a quantitative injection device that can also give improved reliability to the device.

In order to achieve the above object, the quantitative drug injection device according to the present invention is connected to a pipe for fire fighting or water treatment and the like, and an inlet and an outlet are formed to allow the flow of water flowing through the pipe to be formed therein. A main pump provided with a rotational force generating unit for obtaining rotational force by water flow; A pumping part is provided to receive a rotational force of the main pump to generate a predetermined pumping force, one end of which is connected to a drug supply path of an external drug tank through a joint, and the other end of the outlet of the main pump through a drug injection path. An auxiliary pump connected to the medicine tank to inject the medicine from the medicine tank; And a transmission disposed between the main pump and the auxiliary pump to shift the rotational force of the main pump to the auxiliary pump.

In addition, the rotational force generating portion of the main pump, a pair of rotary shafts which are respectively upright fixedly arranged on both sides of the water flow of the pipe and a pair of rotors that are coupled to each other in the state coupled to each other in a shaft coupled to the pair of rotary shafts. Can be configured.

One side of the main pump may be further provided with a gear box having a plurality of gear pairs to be coupled with the rotating shaft to transfer the rotational force or to change the rotational speed so as to continuously maintain the same rotation rate of each rotor. .

The pumping part of the auxiliary pump is provided with a high-pressure piston for injecting drugs at a high pressure even when the water pressure of the pipe is high, the power for connecting the main pump and the transmission and the transmission and the auxiliary pump to transfer power The disc coupling may be provided as the transfer means.

A check valve for controlling the flow of the drug forward and reverse on the drug injection path may be further provided, the main pump and the pipe and the auxiliary pump is connected to each other by connecting the joint of the auxiliary pump and the main pump. A flushing tube may be further provided to wash the main pump, the pipe and the auxiliary pump. When the drug is injected between the joint of the flushing tube and the auxiliary pump, the drug flow to the flushing tube is blocked and washed. A three-way valve may be further provided to control the flow of water so that the washing water may be supplied to the flushing pipe.

In addition, a filter may be further provided on the flushing pipe to block foreign substances from flowing into the auxiliary pump, and a manual drain valve may be further provided on the bottom of the main pump to discharge the liquid in the main pump to the outside. And, when the pressure in the pipe on the main pump is low may be further provided with an automatic drain valve that is automatically opened to discharge the fluid that is accumulated in the main pump to the outside.

In addition, an antifreeze injection unit may be further connected to one side of the auxiliary pump to inject an antifreeze into the auxiliary pump, and connected to the discharge side of the high pressure piston among the auxiliary pumps, and the suction time of the high pressure piston of the auxiliary pump may be An air discharge unit may be further provided to quickly discharge the sucked air so as to shorten the pressure.

In addition, a manual rotation manipulation unit may be further provided at one side of the transmission to be connected to the transmission gear shaft inside the transmission to check whether the transmission gear shaft and the like are fixed by manual rotation operation.

As described above, the quantitative drug injection device according to the present invention is connected to a pipe for firefighting or water treatment, etc., but the main pump having a lobe-type rotor consisting of two shafts to obtain rotational force by the flow of water, and By providing the auxiliary pump for receiving the rotational force of the main pump to generate a predetermined pumping force and a transmission disposed between the main pump and the auxiliary pump to shift the rotational power of the main pump to the auxiliary pump, the water flow of the water treatment basically The use of power generation eliminates the need for a separate power source, which in turn leads to cost savings due to semi-permanent energy saving of the device, resulting in improved competitiveness of the device, as well as high eccentricity by two shafts. Rotation is possible to minimize noise and vibration.

In addition, by increasing the rotation rate of the auxiliary pump by the transmission between the main pump and the auxiliary pump so that the mixing ratio can be adjusted even at the minimum flow rate, the injection rate of the drug is always corrected through the constant pumping force of the auxiliary pump regardless of the flow rate of the pipe. As a result, it is possible to improve the workability and work efficiency as a result, and the overall reliability of the device is obtained.

In addition, by applying a lobe (vane) rotor having excellent adhesion to the double-axis fixed rotation as the rotational force generating portion of the main pump, it is possible to precisely inject the drug while allowing quantitative flow by minimizing the gap. Again, the effect can be given to improving the reliability of the device.

1 is a perspective view showing the external appearance of a quantitative injection device according to an embodiment of the present invention.
Figure 2 is a schematic diagram showing the interior of the quantitative injection device according to an embodiment of the present invention.
Figure 3 is a schematic diagram showing a state in which the quantitative injection device according to an embodiment of the present invention is installed on the pipe.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 to 3, the quantitative drug injection device according to an embodiment of the present invention is connected on the pipe 10 for firefighting or water treatment, and the inlet, outlet 21, 22 and rotational force generating unit ( The auxiliary pump 30 and the main pump 20 provided with the main pump 20 and the pumping unit 31 which receives the rotational force of the main pump 20 to generate a predetermined pumping force are provided. It is set as the structure containing the transmission 40 arrange | positioned between the pump 30. As shown in FIG.

1 and 2, the main pump 20 is connected between the pipe 10 for firefighting or water treatment, etc., but the inlet 21 opened toward the side in which the water flow flowing through the pipe 10 is introduced. And an outlet 22 which is disposed opposite to the same line of the inlet 21 and is opened to discharge the water flow therein, and has a rotational force generating unit 23 for obtaining rotational force while being axially rotated by the water flow. Has a structure provided.

Here, the edges of the inlet 21 and the outlet 22 are each flange-shaped to facilitate the connection with the pipe 10.

In addition, the rotation force generating unit 23 of the main pump 20 is provided on a pair of rotary shafts 23a and the pair of rotary shafts 23a, which are respectively fixedly arranged on both sides of the water flow of the pipe 10. A pair of lobe (vane) rotor (23b) is configured to axially rotate by engaging the outer circumferential surfaces of each other in an axially coupled state, respectively.

Here, the lobe (vane) rotor (23b) is, for example, three circular arc projections (23b1) and three arc projections (protruding in an arc shape toward each of the three radial directions to form a right angle along the circumferential direction in the central axis ( It has a cross-sectional uneven circumferential shape consisting of three arc immersion portions 23b2 immersed in a circular arc shape between 23b1), and this cross-sectional uneven circumferential shape is extended (projected) along a axial direction to realize a predetermined uneven cylinder. As a result, the arc projecting portion 23b1 and the arc immersion portion 23b2 of each of these uneven cylinders are engaged with each other to axially rotate.

This circular interlocking structure minimizes the gap between each other, enabling quantitative flow of water flow, which in turn enables metering of the drug, as well as high-speed rotation without eccentricity by two shafts, minimizing noise and vibration. It is to be possible.

In addition, the bottom surface of the main pump 20 is provided with a manual drain valve 27 for discharging the liquid in the main pump 20 to the outside after the use of the quantitative drug injection device of the present invention.

Here, the manual drain valve 27 is composed of a pair provided on both sides of the bottom surface of the main pump 20 so as to completely discharge the liquid that may accumulate on the entire bottom surface of the main pump 20 to the outside.

In addition, when the pressure in the pipe 10 is low on the main pump 20, the fluid that accumulates in the main pump 20 (especially in the winter season is a freezing factor and interferes with driving of the device) is automatically discharged to the outside. An automatic drain valve 28 for opening is provided.

On the one side of the main pump 20, a plurality of gears are engaged with the rotating shaft 23a to transmit the rotational force or change the rotational speed so as to continuously maintain the rotational ratio of the respective rotors 23b. A gearbox 25 having a pair is provided.

1 and 2, the auxiliary pump 30 is provided with a pumping part 31 for receiving a rotational force of the main pump 20 to generate a predetermined pumping force, one end of which is connected to the joint 32. It is connected to the drug supply path 12 of the external drug tank 11 through the other end thereof is connected to the outlet 22 of the main pump 20 through the drug injection path 33 is the drug tank (11) Chemicals are designed to be injected into the pipe (10).

Here, the pumping part 31 of the auxiliary pump 30 may be provided with a high-pressure piston to inject the drug at a high pressure even when the water pressure of the pipe 10 is high.

In addition, one side of the auxiliary pump 30 is provided with an antifreeze injection unit 70 for injecting antifreeze into the auxiliary pump 30 to prevent freezing in winter.

In addition, an air discharge part 80 is provided to quickly discharge the sucked air so as to be connected to the discharge side of the high pressure piston of the auxiliary pump 30 so as to shorten the suction time of the high pressure piston of the auxiliary pump 30. have.

1 and 2, the transmission 40 is disposed between the main pump 20 and the auxiliary pump 30 to supply the rotational force of the main pump 20 to the auxiliary pump 30. As the main coupling 20, the transmission 40 and the disc coupling 50 as a power transmission means for smoothly performing power transmission by connecting between the transmission 40 and the auxiliary pump (30). This is provided.

In this case, when the transmission 40 is not used, the transmission flow rate of the auxiliary pump 30 is too small at the minimum flow rate of the main pump 20 so that the mixing ratio may not be met by the transmission 40. As the rotation rate of the auxiliary pump 30 can be increased, the mixing ratio can always be adjusted even at the minimum flow rate.

In addition, one side of the transmission 40 is connected to the transmission gear shaft 41 inside the transmission 40 to determine whether the transmission gear shaft 41 or the like is fixed by manual rotation operation of the transmission 40. There is provided a manual rotation operation unit 90 to check from the outside without.

In addition, a check valve 34 for controlling the flow of the drug forward and backward on the drug injection path 33 is provided.

In addition, the main pump 20, the pipe 10, and the auxiliary pump 30 communicate with each other by connecting the joint 32 of the auxiliary pump 30 and the inlet 21 of the main pump 20. A flushing tubular body 60 is provided to wash the main pump 20, the pipe 10, and the auxiliary pump 30.

Here, in order to wash the main pump 20 and the auxiliary pump 30 by blocking the inflow of the washing water into the pipe 10, the main valve 15 and the auxiliary valve 16 on the pipe 10 are to be removed. The wash may be performed by blocking.

Then, between the flushing pipe 60 and the joint 32 of the auxiliary pump 30 to block the flow of the drug to the flushing pipe 60 during the injection of the drug and to supply the washing water to the flushing pipe 60 during the cleaning Three-way valve 35 for controlling the flow of water flow is provided.

In addition, a filter 61 is provided on the flushing pipe 60 to block foreign substances from entering the auxiliary pump 30.

In addition, the materials of the main pump 20 and the auxiliary pump 30 may be made of stainless steel, which can completely solve the fear of damage during installation, and of course, have low thermal conductivity as compared with aluminum, so that there is no fear of freezing.

Referring to FIG. 3, reference numeral 13 denotes a water source in which water forming water flow onto the pipe 10 is stored, and 14 denotes a water source 13 for pumping the quantitative drug injection device of the present invention. The pump is shown, 15 is the main valve on the pipe 10, 16 is the auxiliary valve installed on the discharge port.

Looking at the drug injection process into the pipe 10 through the quantitative drug injection device which is an embodiment of the present invention according to such a configuration, first, for example, the main pump 20 between the pipe 10 for fire fighting or water treatment, etc. Connect the inlet 21 and outlet 22 of each.

Then, the water flow of the pipe 10 is introduced into the interior through the inlet 21 of the main pump 20 to pass through the rotational force generating unit 23 while allowing the rotational force generating unit 23 to rotate the shaft (outlet) 22).

Thus, the rotational force generating unit 23 of the main pump 20 is axially rotated by the water flow in the pipe 10 to generate a predetermined power without a separate power source.

Then, the rotational force of the main pump 20 is transmitted to the transmission 40 through the disc coupling 50 and then assisted through another disc coupling 50 by the set gear speed ratio of the transmission 40. The set rotational force is transmitted to the pump 30 to drive the pumping part 31 of the auxiliary pump 30.

Then, the medicament of the drug tank 11 is pumped by the pumping force of the pumping part 31 is supplied along the medicament injection path 33 and then pipe 10 through the outlet 22 of the main pump 20 Injecting the drug into the) will be made.

In this case, the pumping part 31 allows the sucked air to be quickly discharged through the air discharge part 80 to shorten the suction time of the high pressure piston of the auxiliary pump 30 to maintain the high pressure pumping force. It can be done with.

In addition, the drug injection into the pipe 10, the transmission 40 provides a constant power to the auxiliary pump 30 irrespective of the water flow changes in the pipe 10, and as a result the drug is continuously by a constant pumping force Is metered in.

And, the flow of the drug back in the drug injection process is to be blocked in advance by the check valve 34 on the drug injection path (33).

In this way, when the rotational force generating portion (lobe / vane rotor) 23 of the main pump 20 is axially rotated by the water flow of the pipe 10, the auxiliary power 30 is supplied to the auxiliary pump 30 through the transmission 40. After the drug in the medicine tank 11 is pumped in the medicine supply passage 12 by the pumping part 31 having the high pressure piston of the pump 30, the pipe 10 continues through the medicine injection passage 33. While being injected into the drug supply operation to the water flow in the pipe 10 is made continuously.

At this time, the three-way valve 35 of the joint 32 is opened so that the flow to the flushing pipe 60 of the drug is blocked to flow only into the auxiliary pump (30).

In addition, when the pressure in the pipe 10 is low through the automatic drain valve 28 on the main pump 20 during the drug injection process, the fluid which is accumulated in the main pump 20 is quickly discharged to the outside, in particular. It is possible to prevent the freezing of the fluid which may be a freezing factor in the winter and interfere with the operation of the quantitative injection device of the present invention.

On the other hand, if you want to perform the flushing operation in a state in which the drug supply operation is stopped, the connection to the drug supply passage 12 in the joint 32 of the auxiliary pump 30 is released and a separate washing water supply line (not shown) ) And the three-way valve 35 is operated to open the flow to the flushing tubular body 60 to supply the washing water, and the washing water is carried on the flushing tubular body 60 to the main pump 20. The pipe 10 and the auxiliary pump 30 are circulated to wash them.

In the flushing operation, the main valve 15 and the auxiliary valve 16 of the pipe 10 are closed to block the flow of the washing water to the pipe 10, and then only the main pump 20 and the auxiliary pump 30 are circulated. You can also have the washing done.

This washing process is circulated in the direction of the drug injection path 33 through the auxiliary pump 30, the washing water passes through the main pump 20 through the check valve 34, and then circulated back to the auxiliary pump 30, such Foreign matter, etc. on the main pump 20 side during the circulation process is blocked by the filter 61 is introduced into the auxiliary pump (30).

In addition, the fluid remaining in the main pump 20 after the operation is completed to be discharged to the outside through the manual drain valve 27 to prevent the freezing, especially in winter.

In addition, the antifreeze is also supplied to the auxiliary pump 30 through the antifreeze injection unit 70 in advance to prevent freezing.

In addition, after the completion of the work or when the temporary work stops, the manual rotation operation unit 90 provided on one side of the transmission 40 is operated to check whether the transmission gear shaft 41 and other equipment are stuck and smooth drug injection work is continued. To be performed.

As described above, the quantitative drug injection device according to an embodiment of the present invention is connected to a pipe for fire fighting or water treatment, but the main pump to obtain a rotational force by the water flow, and receives the rotational force of the main pump predetermined A subsidiary pump generating a pumping force of the main pump and a transmission disposed between the main pump and the subsidiary pump is provided with a transmission for shifting and supplying the rotational force of the main pump to the subsidiary pump. This eliminates the need to reduce the cost of the device and, consequently, improves the competitiveness of the device. In addition, the transmission between the main pump and the sub-pump allows a constant amount of auxiliary pump regardless of the flow rate of the pipe flow. The pumping force ensures that the dose of drug is always injected at the correct rate. By improving the workability and work efficiency, the overall reliability of the apparatus is improved. In addition, by applying a lobe (vane) rotor having excellent adhesion, which is a dual-axis fixed rotation as the rotational force generating portion of the main pump. By minimizing the gap, it is possible to precisely inject the drug while allowing quantitative flow, which can also give an improved reliability of the device.

On the other hand, the present invention is because the basic system configuration is a non-powerless application field using the same, it is possible to drastically change the fan equipment used in the cooling tower, all the cooling equipment for the cooling tower used in the existing buildings or factories always use the power Compared to the yearly power consumption as a motor-type fan facility, semi-permanent energy savings can be expected when building facilities through the application of the present invention.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, It should be understood that all of the techniques that can be easily changed and used by those skilled in the art are included in the technical scope of the present invention.

10: piping 11: chemical tank
12: Supply path 13: Suwon
14 pump 15 main valve
16: auxiliary valve 20: main pump
21: inlet 22: outlet
23: rotational force generating unit 23a: rotation axis
23b: rotor 23b1: arc protrusion
23b2: arc immersion part 25: gearbox
27: manual drain valve 28: automatic drain valve
30: auxiliary pump 31: pumping unit
32: joint 33: chemical injection
34: check valve 35: 3-way valve
40: transmission 41: transmission gear shaft
50: disc coupling 60: flushing pipe
61 filter 70 antifreeze injection unit
80: air discharge unit 90: manual rotation control unit

Claims (9)

A main pump connected to a pipe for firefighting or water treatment, and having an inlet and an outlet for inflow and outflow of the water flowing through the pipe, and having a rotational force generating unit configured to obtain a rotational force by the current;
A pumping part is provided to receive a rotational force of the main pump to generate a predetermined pumping force, one end of which is connected to a drug supply path of an external drug tank through a joint, and the other end of the outlet of the main pump through a drug injection path. An auxiliary pump connected to the medicine tank to inject the medicine from the medicine tank; And
And a transmission disposed between the main pump and the auxiliary pump to shift the rotational force of the main pump to the auxiliary pump.
The pumping unit of the auxiliary pump is provided with a high-pressure piston for applying a pressure to inject the medicament,
Disc injection is provided as a power transmission means for transmitting power by connecting between the main pump and the transmission and the transmission and the auxiliary pump.
The method of claim 1,
Rotation force generating portion of the main pump,
A pair of rotary shafts disposed upright and fixed to both sides of the water flow of the pipe; And
It is configured to include;
One side of the main pump is geared with the rotary shaft so as to continuously maintain the same rotation ratio of the respective rotors is further provided with a gear box having a plurality of gear pairs for transmitting a rotational force or to change the rotational speed Quantitative drug injection device.
delete The method of claim 1,
Quantitative drug injection device further comprises a check valve for controlling the flow of the drug forward and reverse on the drug injection path.
The method of claim 1,
The flushing pipe body is further provided to connect the joint of the auxiliary pump and the main pump to the main pump, the pipe and the auxiliary pump to communicate with each other to wash the main pump, the pipe and the auxiliary pump. Drug injection device.
The method of claim 5,
When the injection of the drug between the joint of the flushing pipe and the auxiliary pump is provided with a three-way valve to block the flow of the drug to the flushing pipe and to control the flow of water flow to supply the washing water to the flushing pipe,
The quantitative drug injection device, characterized in that further provided with a filter for blocking the foreign matter flow into the auxiliary pump on the flushing pipe.
The method of claim 1,
A manual drain valve is further provided on the bottom of the main pump to discharge the liquid in the main pump to the outside.
When the pressure in the pipe on the main pump is low, the fixed amount drug injection device further comprises an automatic drain valve that is automatically opened to discharge the fluid that collects in the main pump to the outside.
The method of claim 1,
It is further provided with an antifreeze injection unit connected to one side of the auxiliary pump to inject an antifreeze into the auxiliary pump,
A quantitative medicine injection device further comprising an air discharge portion connected to the discharge side of the high pressure piston of the auxiliary pump to quickly discharge the sucked air to shorten the suction time of the high pressure piston of the auxiliary pump.
The method of claim 1,
A fixed amount pharmaceutical injection device is connected to the transmission gear shaft inside the transmission on one side of the transmission to allow the manual rotation operation to check whether the transmission gear shaft is fixed.

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