Patent Publication Number: US-2023151723-A1

Title: Turbine Fracturing Apparatus and Turbine Fracturing Well Site

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     For all purposes, this patent application claims the benefit of priority to the Chinese Patent Application No. 202111368299.2 filed on Nov. 18, 2021, and is a continuation application of and claims the benefit of priority to International Application No. PCT/CN2022/071607 filed on Jan. 12, 2022 which is also based on and claims the benefit of priority to Chinese Patent Application No. 202111368299.2 filed on Nov. 18, 2021. The above-identified priority applications are herein incorporated by reference in their entireties. 
    
    
     TECHNICAL FIELD 
     The embodiments of the present disclosure relate to a turbine fracturing apparatus and turbine fracturing well site. 
     BACKGROUND 
     There are two main driving mechanisms for fracturing apparatus in oil and gas-field fracturing operation sites. 
     The first driving mechanisms is to use a diesel engine to drive the fracturing operation. For example, in this driving mechanisms, the diesel engine is connected with a gearbox to drive a fracturing pump to operate through a transmission shaft. In other words, the power source is the diesel engine, the transmission device includes the gearbox and the transmission shaft, and the actuator is a plunger pump. 
     The second driving mechanism is via electric power. For example, in this driving mechanism, an electric motor is connected with a transmission shaft or a coupling to drive the plunger pump to operate. The power source thereof thus includes the electric motor. The transmission device includes the transmission shaft or the coupling, and the actuator is a plunger pump. 
     SUMMARY 
     The embodiments of the present disclosure provide a turbine fracturing apparatus and a turbine fracturing well site to increase the utilization rate of unit operating area of the well site. 
     The embodiments of the present disclosure provide a turbine fracturing apparatus, including: a turbine engine, configured to provide power; a deceleration device, having an input end and a plurality of output ends, the input end being connected with the turbine engine; a plurality of plunger pumps, connected with the plurality of output ends, respectively, each of the plurality of plunger pumps being configured to suck low-pressure fluid and discharge high-pressure fluid; and an auxiliary power unit, configured to provide auxiliary power to at least one selected from the group consisting of the turbine engine, the deceleration device, and each of the plurality of plunger pumps; the auxiliary power unit, the turbine engine, and the deceleration device are sequentially arranged. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the plurality of plunger pumps may be arranged at a same side of the deceleration device. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the deceleration device includes a long edge and a short edge, and the plurality of plunger pumps are arranged at a side of the deceleration device along the long edge of the deceleration device. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the turbine engine is arranged at a side of the deceleration device along the short edge of the deceleration device. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the turbine engine is arranged at a side of the deceleration device opposite to the side of the deceleration device where the plurality of plunger pumps may be provided. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the deceleration device includes an input shaft and a plurality of output shafts, the turbine engine is connected with the input end of the deceleration device through the input shaft, and the plurality of output shafts are connected with the plurality of output ends of the deceleration device, respectively. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the plurality of plunger pumps may be arranged at both sides of the deceleration device, respectively. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the turbine engine is located above one of the plurality of plunger pumps. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the plurality of plunger pumps may include two plunger pumps, and the two plunger pumps are connected with two ends of a same output shaft of the deceleration device, respectively. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the auxiliary power unit and the deceleration device are arranged at both sides of the turbine engine, respectively. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the auxiliary power unit includes an auxiliary motor, and the turbine engine or the deceleration device is provided with a power take-off port to drive the auxiliary motor. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the auxiliary power unit includes at least one selected from the group consisting of a lubricating unit, a cooling unit, an air supplying unit, and a ventilating unit, and the auxiliary motor includes at least one selected from the group consisting of a lubricating motor, a cooling motor, an air supplying motor, and a ventilating motor. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the turbine fracturing apparatus further includes a clutch, one clutch is provided between each of the plurality of plunger pumps and the deceleration device. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the turbine fracturing apparatus further includes a connecting structure, each of the plurality of plunger pumps is connected with the deceleration device through one connecting structure, and the clutch is closer to the deceleration device than the connecting structure. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the turbine fracturing apparatus further includes a connecting structure, each of the plurality of plunger pumps is connected with the deceleration device through a connecting structure. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the turbine fracturing apparatus further includes a base, the base includes a long edge and a short edge, and the turbine engine and the deceleration device are sequentially arranged along an extending direction of the long edge of the base. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the auxiliary power unit, the turbine engine, and the deceleration device are sequentially arranged along the extending direction of the long edge of the base. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, the plurality of plunger pumps may be in contact with the base, and are sequentially arranged along the long edge or short edge of the base. 
     According to the turbine fracturing apparatus provided by an embodiment of the present disclosure, an interval is provided between the turbine engine and the plurality of plunger pumps in a direction perpendicular to a main surface of the base. 
     The embodiments of the present disclosure further provide a turbine fracturing well site, including any one of the turbine fracturing apparatuses as described above. 
     According to the turbine fracturing well site provided by an embodiment of the present disclosure, the turbine fracturing well site further includes a manifold skid, wherein each of the plurality of plunger pumps includes a discharge end, the discharge end of each of the plurality of plunger pumps is configured to discharge the high-pressure fluid, and discharge ends of the plurality of plunger pumps are arranged towards the manifold skid. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In order to illustrate the technical solution of the embodiments of the present disclosure, the drawings of the embodiments are briefly described below. The drawings are only related to some example embodiments of the present disclosure and thus are not construed as imposing any limitation to the present disclosure. 
         FIG.  1   - FIG.  6    are layout diagrams of an example turbine fracturing apparatus provided by embodiments of the present disclosure. 
         FIG.  7    is a schematic diagram of an example turbine fracturing apparatus including a connecting structure provided by an embodiment of the present disclosure. 
         FIG.  8    is a schematic diagram of an example turbine fracturing apparatus including a clutch provided by an embodiment of the present disclosure. 
         FIG.  9    is a schematic diagram of an example turbine fracturing apparatus including a clutch and a connecting structure provided by an embodiment of the present disclosure. 
         FIG.  10 A  is a schematic diagram of an example turbine fracturing apparatus. 
         FIG.  10 B  is a principle diagram of an example turbine fracturing hydraulic system. 
         FIG.  10 C  is a schematic diagram of an example turbine fracturing apparatus provided by an embodiment of the present disclosure. 
         FIG.  11    is a schematic diagram of an example turbine fracturing well site provided by an embodiment of the present disclosure. 
     
    
    
     DETAILED DESCRIPTION 
     In order to explain the objectives, technical details and advantages of the embodiments of the present disclosure, the technical solutions of the embodiment are described below in connection with the drawings related to the embodiments of the present disclosure. The described embodiments are merely examples and do not encompass all of the embodiments of the present disclosure. Based on the described embodiments herein, those having ordinary skill in the art can obtain other embodiment(s), without any inventive work. Those embodiments should be considered as being within the scope of the present disclosure. 
     Unless otherwise defined, all the technical and scientific terms used herein have the same meanings as commonly understood by one of ordinary skill in the art to which the present disclosure belongs. The terms “first,” “second,” etc., which are used in the present disclosure, are not intended to indicate any sequence, amount or importance, but distinguish various components. Also, the terms “comprise,” “comprising,” “include,” “including,” etc., are intended to specify that the elements or the objects stated before these terms encompass the elements or the objects and equivalents thereof listed after these terms, but do not preclude the other elements or objects. The phrases “connect”, “connected”, etc., are not intended to define a physical connection or mechanical connection, but may include an electrical connection, directly or indirectly. “On,” “under,” “right,” “left” and the like are only used to indicate relative position relationship, and when the position of the described object is changed, the relative position relationship may be changed accordingly. 
     In terms of the driving manner (or scheme) by using a diesel engine, the configuration mode has the following disadvantages: it will produce exhaust gas and noise pollution exceeding, e.g., 105 dBA; the engine is bulky and cannot realize high-power operation; and the initial cost and the later maintenance cost are high and uneconomical. 
     In terms of electric drive fracturing, the electric drive fracturing itself has many advantages and can reduce noise pollution and meet the requirements of high-power operation. However, it needs arrangement of electric power supply apparatuses in advance, which is the prerequisite for the implementation of electrically driven fracturing operation. The electric power supply problem of the fracturing well site is not easy to solve. Either the power grid capacity of the well site is too small to supply the whole fracturing set, or there is no power grid at the well site at all. Therefore, electric generators are usually used to provide electricity in typical electric drive fracturing sites, and the most economical fuel for power generation is natural gas. The use of natural gas, however requires operators to rent or purchase gas-fired generator set. For a fracturing well site without power grid, the power of the gas-fired generator set needs to reach at least 30 MW, which may require a considerable investment for the operators to purchase such a large power gas-fired generator set. Moreover, in the actual well-site operation process, the whole electric drive fracturing set may be paralyzed as a result of a failure of the gas-fired generator set, which will seriously affect the operation quality and may even lead to operation accidents. 
     Usually, the turbine fracturing apparatus includes a single turbine engine and a single plunger pump, and the utilization rate of unit operating area of the well site is not high. A failure of the plunger pump will lead to the shutdown of the whole apparatus. The existing apparatus is noisy and will cause noise pollution to the environment. The turbine engine of the existing apparatus is only configured to drives the plunger pump, and the utilization of the turbine engine is not high. 
       FIG.  1   - FIG.  6    are layout diagrams of example turbine fracturing apparatus provided by various embodiments of the present disclosure. As illustrated in  FIG.  1   - FIG.  6   , the turbine fracturing apparatus  10  may include a turbine engine  1 , a deceleration device  2 , a plunger pump  3 , and an auxiliary power unit  4 .  FIG.  1   - FIG.  6    illustrate example turbine fracturing apparatuses  10   a ,  10   b ,  10   c ,  10   d ,  10   e  and  10   f , respectively. 
     As illustrated in  FIG.  1   - FIG.  6   , the turbine engine  1  may be configured to provide power. The deceleration device  2  has an input end  21  and a plurality of output ends  22 , and the input end  21  may be connected with the turbine engine  1 . A plurality of plunger pumps  3  may be connected with the plurality of output ends  22 . The plunger pump  3  may be configured to draw/suck/intake low-pressure fluid and discharge high-pressure fluid. The auxiliary power unit  4  may be configured to provide auxiliary power to at least one of the turbine engine  1 , the deceleration device  2 , and the plunger pumps  3 , or the auxiliary power unit  4 . The turbine engine  1  and the deceleration device  2  may be sequentially arranged. The turbine engine  1  may be configured to drive the plunger pumps. 
     The example turbine fracturing apparatus provided by the embodiment of the present disclosure adopts a single turbine engine and multiple pumps. That is, one turbine engine may be configured to drive a plurality of plunger pumps, thus improving the utilization rate of unit operating area of the well site. The output power of a single apparatus (turbine fracturing set) is large, which can replace at least two ordinary diesel fracturing trucks. The displacement of fracturing fluid by the plunger pump can also be more stable under such a configuration. 
     When two plunger pumps are used, a structure of single turbine engine and double pumps is formed. That is, one turbine engine operates to drive two plunger pumps. The embodiments of the present disclosure are described with reference to the case where one turbine engine drives two plunger pumps, merely by way of example. 
     The fracturing apparatus having a single turbine engine and multiple pumps (e.g., single turbine engine and double pumps) provided by the embodiment of the present disclosure is used to increase the operating power of the fracturing apparatus and to increase the utilization efficiency per unit area of the well site. Moreover, the noise level of the apparatus is lowered by using a single turbine engine, which reduces the noise pollution to the environment. 
     As illustrated in  FIG.  1   - FIG.  6   , according to the turbine fracturing apparatus provided by the embodiment of the present disclosure, the turbine fracturing apparatus may further include a base  5 . The base may include a long edge  501  and a short edge  502 , and the turbine engine  1  and the deceleration device  2  may be sequentially arranged along the extending direction of the long edge  501  of the base  5 . The length of the long edge  501  may be greater than that of the short edge  502 . In some example implementations, two long edges  501  may be arranged opposite to each other, and two short edges  502  may be arranged opposite to each other. 
     For example, as illustrated in  FIG.  1   - FIG.  2    and  FIG.  4   - FIG.  5   , the long edge  501  may extend in the direction X and the short edge  502  may extend in the direction Y. 
     As illustrated in  FIG.  1   - FIG.  6   , according to the turbine fracturing apparatus provided by the embodiment of the present disclosure, two plunger pumps  3  may be in contact with the base  5 , and may be sequentially arranged along the long edge  501  or the short edge  502  of the base  5 . The figures further illustrate a plan view of the base with a shape of rectangle, but the shape of the base is not limited to a rectangle, and other suitable shapes can be adopted as needed. 
     As illustrated in the examples of  FIG.  1   - FIG.  6   , in order to facilitate the layout of each component, the auxiliary power unit  4 , the turbine engine  1 , and the deceleration device  2  may be sequentially arranged along the extending direction of the long edge  501  of the base  5 . 
     As illustrated in the examples of  FIG.  1   - FIG.  6   , the turbine engine  1 , the deceleration device  2 , the plunger pumps and the like may be disposed/placed on the base  5 . For example, the base  5  can be skid-mounted, vehicle-mounted or semi-trailer. 
     As illustrated in the examples of  FIG.  1   - FIG.  6   , the turbine engine  1  may be connected with the input end  21  of the deceleration device  2 . The deceleration device  2  may be configured with at least a plurality of output ends  22 , and the plunger pumps  3  are connected with the output ends  22  of the deceleration device  2 . In some example implementations, the plunger pumps  3  and the deceleration device  2  can also be connected by using a transmission device. 
     As illustrated in  FIG.  1   ,  FIG.  2   ,  FIG.  4    and  FIG.  5   , according to the example turbine fracturing apparatus provided by the embodiment of the present disclosure, in order to facilitate the layout of the turbine fracturing apparatus and to balance the weight distribution of the plunger pumps, two plunger pumps  3  may be arranged at the same side of the deceleration device  2 . The plunger pumps  3  may be arranged at the same side of the deceleration device  2 , which is beneficial to the arrangement of other components. 
     As illustrated in  FIG.  1   - FIG.  6   , the deceleration device  2  may include a long edge  201  and a short edge  202 , and the length of the long edge  201  may be greater than that of the short edge  202 . As illustrated in  FIG.  1   - FIG.  6   , two long edges  201  may be arranged opposite to each other, and two short edges  202  may be arranged opposite to each other.  FIG.  1    and  FIG.  2    illustrate the deceleration device  2  with a shape of rectangle. However, the plan view of the deceleration device  2  is not limited to a rectangle, and other suitable shapes can be adopted as needed. For example, the long edge  201  and the short edge  202  of the deceleration device  2  may be the long edge and the short edge of the bottom surface of the deceleration device  2 . However, they may not be so limited. For example, the long edge  201  and the short edge  202  of the deceleration device  2  can also be the long edge and the short edge of the orthographic projection of the deceleration device  2  on the base  5 . For example, the long edge  201  and the short edge  202  of the deceleration device  2  can also be the long edge and the short edge of part of the deceleration device  2  that is in contact with the base  5 . For example, the long edge  201  of the deceleration device  2  may correspond to a first side surface of the deceleration device  2 , whereas the short edge  202  of the deceleration device  2  may correspond to a second side surface of the deceleration device  2 . Two first side surfaces of the deceleration device  2  may be arranged opposite to each other, and two second side surfaces of the deceleration device  2  may be arranged opposite to each other. The first side surface and the second side surface of the deceleration device  2  may be adjacent to each other. 
     As illustrated in  FIG.  1    and  FIG.  4   , according to the example turbine fracturing apparatus provided by the embodiment of the present disclosure, in order to facilitate the layout of the turbine fracturing apparatus and to balance the weight distribution of the plunger pumps, two plunger pumps  3  may be arranged at the side of the deceleration device  2  along the long edge  201  of the deceleration device  2 . 
     As illustrated in  FIG.  1    and  FIG.  4   , according to the example turbine fracturing apparatus provided by the embodiment of the present disclosure, in order to make the turbine engine and the plunger pumps be arranged at different sides of the deceleration device  2 , the turbine engine  1  may be arranged at the side of the deceleration device  2  along the short edge  202  of the deceleration device  2 . 
     As illustrated in  FIG.  2    and  FIG.  5   , according to the turbine fracturing apparatus provided by the embodiment of the present disclosure, in order to make the turbine engine and the plunger pumps be arranged at different sides of the deceleration device  2 , the turbine engine  1  may be arranged at the side of the deceleration device  2  that is opposite to the side of the deceleration device  2  where two plunger pumps  3  are provided. As illustrated in  FIG.  2    and  FIG.  5   , the auxiliary power unit  4 , the turbine engine  1 , the deceleration device  2 , and a plunger pump group consisting of the plurality of plunger pumps  3  may be sequentially arranged in the direction X. The plurality of plunger pumps  3  in the plunger pump group may be sequentially arranged in the direction Y. 
     As illustrated in  FIG.  1   - FIG.  6   , according to the turbine fracturing apparatus provided by the embodiment of the present disclosure, the deceleration device  2  may include an input shaft  211  and a plurality of output shafts  212 . The turbine engine  1  may be connected with the input end  21  of the deceleration device  2  through the input shaft  211 , and the plurality of output shafts  212  may be connected with the plurality of output ends  22  of the deceleration device  2 . The number of output shafts  212  can be equal to the number of plunger pumps  3 , but it is not limited thereto. In some embodiments, the number of output shafts  212  can be greater than the number of plunger pumps  3 , and output shafts  212  can be provided for auxiliary components. 
     As illustrated in  FIG.  3    and  FIG.  6   , according to the example turbine fracturing apparatus provided by the embodiment of the present disclosure, in order to arrange the plunger pumps dispersedly, two plunger pumps  3  may be arranged at both sides of the deceleration device  2 , respectively. As illustrated in  FIG.  3    and  FIG.  6   , two plunger pumps may be sequentially arranged in the direction X. As illustrated in  FIG.  3    and  FIG.  6   , the auxiliary power unit  4 , one plunger pump  3 , the deceleration device  2 , and the other plunger pump  3  may be sequentially arranged in the direction X. 
     As illustrated in  FIG.  3    and  FIG.  6   , according to the example turbine fracturing apparatus provided by the embodiment of the present disclosure, in order to reduce the size of the base  5  and make the structure of the turbine fracturing apparatus more compact, the turbine engine  1  may be located above one of the two plunger pumps  3 . For example, the turbine engine  1  may be located directly above or laterally above one plunger pump  3 . 
     For example, the turbine engine  1  being directly above the plunger pump  3  refers to that the orthographic projection of the turbine engine  1  on the base  5  is within the orthographic projection of the plunger pump  3  on the base  5 . For example, the turbine engine  1  being laterally rather than directly above the plunger pump  3  refers to that the orthographic projection of the turbine engine  1  on the base  5  at most partially overlaps or does not entirely overlap with the orthographic projection of the plunger pump  3  on the base  5 . 
     As illustrated in  FIG.  3    and  FIG.  6   , according to the example turbine fracturing apparatus provided by the embodiment of the present disclosure, an interval  13  may be provided between the turbine engine  1  and the plunger pumps  3  in the direction perpendicular to the main surface  510  of the base  5 . 
     For example, in the embodiment of the present disclosure, the direction perpendicular to the main surface  510  of the base  5  is referred to as direction Z, and the directions parallel with the main surface  510  of the base  5  includes direction X and direction Y. The direction X intersects with the direction Y. The embodiment of the present disclosure is described with reference to the case where the direction X is perpendicular to the direction Y, by way of example. 
     For example, as illustrated in  FIG.  1   - FIG.  2    and  FIG.  4   - FIG.  5   , the deceleration device  2  may extend in the direction Y, and the auxiliary power unit  4  may extend in the direction Y. 
     As illustrated in  FIG.  3    and  FIG.  6   , the size of the interval  13  in the direction Z may be less than the size of the auxiliary power unit  4  in the direction Z. As illustrated in  FIG.  3    and  FIG.  6   , in order to facilitate the layout of the auxiliary power unit  4 , the turbine engine  1  and the plunger pump  3 , the sum of the size of the interval  13  in the direction Z, the size of the turbine engine  1  in the direction Z and the size of the plunger pump  3  in the direction Z may be less than the size of the auxiliary power unit  4  in the direction Z. However, other embodiment of the present disclosure may not be so limited. 
     As illustrated in  FIG.  3    and  FIG.  6   , according to the example turbine fracturing apparatus provided by the embodiment of the present disclosure, two plunger pumps  3  may be connected with two ends of the same output shaft  212  of the deceleration device  2 , so as to simplify the structure of the deceleration device  2 . 
     As illustrated in  FIG.  3   - FIG.  6   , according to the example turbine fracturing apparatus provided by the embodiment of the present disclosure, in order to facilitate the layout of each component, the auxiliary power unit  4  and the deceleration device  2  may be arranged at both sides of the turbine engine  1 , respectively. 
     As illustrated in  FIG.  4   - FIG.  6   , according to the example turbine fracturing apparatus provided by the embodiment of the present disclosure, the auxiliary power unit  4  may include an auxiliary motor  6 , and the turbine engine  1  or the deceleration device  2  may be provided with a power take-off port  216  to drive the auxiliary motor. The turbine fracturing apparatus  10   d  in  FIG.  4    is illustrated by assuming, as an example, that the power take-off port  216  is provided on the turbine engine  1 . The turbine fracturing apparatus  10   e  in  FIG.  5    and the turbine fracturing apparatus  10   f  in  FIG.  6    are illustrated as another example by assuming that the power take-off port  216  is provided on the deceleration device  2 . As illustrated in  FIG.  5   , the auxiliary motor  6  and the turbine engine  1  may be located at the same side of the deceleration device  2 , and may be both located at the side of the deceleration device  2  along the long edge  201  of the deceleration device  2 . 
     For example, the turbine engine  1  or the deceleration device  2  may be equipped with a power take-off port, which can drive the auxiliary motor to provide power to the auxiliary system and increase the utilization rate of the turbine engine. For example, the auxiliary motor may include a lubricating motor. 
     As illustrated in  FIG.  3    and  FIG.  6   , considering the width of the vehicle, the turbine engine  1  is placed over the plunger pump  3  to prevent the vehicle from being too wide. 
     Because of the heavy weight of the turbine fracturing apparatus, in order to make the turbine fracturing apparatus conform to the laws and regulations of various places, it is necessary to lay out or flatten out all components of the turbine fracturing apparatus. Further, because the weight of the plunger pump accounts for a large proportion of the total system weight, the layout position and weight distribution of the plunger pump are particularly important. At the same time, in order to obtain better reliability, besides the layout position of plunger pump, the layout positions of other components can also be correspondingly designed and adjusted. The layouts of the turbine fracturing apparatuses illustrated in  FIG.  1   - FIG.  6    provided by the embodiments of the present disclosure are beneficial in implementing the decentralized arrangement of plunger pumps to balance the weight distribution of plunger pumps and are beneficial to improving the reliability of the turbine fracturing apparatuses. 
     By arranging each component of the turbine fracturing apparatus, the structure of the vehicle body is made compact, which helps meeting the requirements for the length and width of the vehicle body. According to the laws and regulations of different regions/countries, the layout may be further adjusted to meet the arrangement requirements for the length and width of the vehicle body. 
     The weight of the plunger pump  3  is relatively large, so it is necessary to adjust the weight distribution of the plunger pump  3 . In some embodiments, it is to be avoided to arrange multiple plunger pumps  3  in the same width direction or the same length direction of the base  5 . If it is not allowed to have relatively large weight in the same width direction in some regions, the arrangement of the plunger pumps can be as illustrated in  FIG.  1    or  FIG.  3   . If it is not allowed to have relatively large weight in the same length direction in some regions, the arrangement of the plunger pumps can follow the example manner as illustrated in  FIG.  2    or  FIG.  5   . 
     The deceleration device  2  may include a gearbox and a gear structure provided in the gearbox. The deceleration device  2  can be configured to adjust the torque or speed, or to adjust the speed reduction ratio. By adjusting the structure of the deceleration device  2 , various layouts as illustrated in the figures can be obtained. 
     As illustrated in  FIG.  1    and  FIG.  4   , the extension directions of the input shaft  211  and the output shaft  212  may be different, which requires the change in directions of power transmission. As illustrated in  FIG.  3    and  FIG.  6   , the output shafts  212  can be a same shaft. 
       FIG.  7    is a schematic diagram of a turbine fracturing apparatus including a connecting structure as provided by an embodiment of the present disclosure.  FIG.  8    is a schematic diagram of a turbine fracturing apparatus including a clutch provided by an embodiment of the present disclosure.  FIG.  9    is a schematic diagram of a turbine fracturing apparatus including a clutch and a connecting structure provided by an embodiment of the present disclosure. 
     As illustrated in  FIG.  7    and  FIG.  9   , the turbine fracturing apparatus may further include a connecting structure  7 , so that the plunger pump can be quickly replaced. The arrangement of the connecting structure  7  is beneficial for achieving rapid disassembly and installation of the plunger pump. 
     For example, a quick disassembly method of the plunger pump may include: in the control system, firstly, stopping a plunger pump from operating because a connecting structure  7  is arranged at the joint of the plunger pump  3  and the deceleration device  2 , the plunger pump  3  and the deceleration device  2  can be quickly connected and disconnected, and the bottom mounting seat of plunger pump  3  may be an assembly structure equipped with a lifting point or forklift hole; then moving the plunger pump from the turbine fracturing apparatus onto a predetermined location via the lifting point or forklift hole; next lifting another plunger pump onto the turbine fracturing apparatus, and further, connecting this plunger pump  3  and the deceleration device  2  together via the connecting structure  7 . After that, the plunger pump is started in the control system. 
     As illustrated in  FIG.  8    and  FIG.  9   , a clutch  8  may be provided at the output end  22  of the deceleration device  2 , so as to realize independent control of each output end  22 . That is, the plunger pumps  3  connected with the same deceleration device  2  can be independently controlled to be started or stopped. As illustrated in  FIG.  8    and  FIG.  9   , by controlling the clutches  8 , one of the two plunger pumps  3  connected with the same deceleration device  2  can be started, and the other of the two plunger pumps  3  connected with the same deceleration device  2  can be stopped. The clutch  8  can control the connection or disconnection of the deceleration device  2  and the plunger pump  3 . That is, a plurality of plunger pumps connected with the same deceleration device  2  can be independently controlled. 
     As illustrated in  FIG.  9   , the turbine fracturing apparatus may include a connecting structure  7  and a clutch  8 . The clutch  8  is closer to the deceleration device  2  than the connecting structure  7 . That is, the output end  22  of the deceleration device  2  is successively provided with the clutch  8 , the connecting structure  7 , and the plunger pump  3 . 
     For example, the control method of the turbine fracturing apparatus provided by the embodiment of the present disclosure may include: the control system independently controls each plunger pump, and when the displacement of one plunger pump decreases, the system can increase the displacement of other plunger pumps to ensure a stable output of the total displacement of the whole apparatus. Therefore, the fracturing apparatus can realize a stable output of the total displacement of the whole apparatus. 
       FIG.  7    and  FIG.  9    are illustrated by as an example by assuming that two plunger pumps  3  are arranged at the same side of the deceleration device  2 . In the case where two plunger pumps  3  are provided at both sides of the deceleration device  2 , at least one of the connecting structure  7  and the clutch  8  can also be provided. The arrangement positions of the connecting structure  7  and the clutch  8  can be configured according to the various description above. 
       FIG.  10 A  is a schematic diagram of an example turbine fracturing apparatus  001 , whereas  FIG.  10 B  is an operation-principle diagram of a turbine fracturing hydraulic system. As illustrated in  FIG.  10 B , the solid line refers to the hydraulic fluid. The arrow refers to the running direction of the hydraulic fluid. The dashed line refers to the mechanical connection between components. Referring to  FIG.  10 A  and  FIG.  10 B , the turbine fracturing apparatus  001  may include a vehicle body  100 , a hydraulic oil tank  01 , a fuel tank  02 , an engine  03 , a plunger pump  3 , a turbine engine  1 , a cooling component  32 , a muffler  33 , a deceleration device  2 , and a lubricating oil tank  81 , which are arranged on the vehicle body  100 . For example, the engine  03  may include a diesel engine, and the fuel tank  02  includes a diesel tank. The lubrication module is not limited to only including lubricating oil. For example, lubricating grease may also be used to lubricate the deceleration device  2 . For example, lubricating grease that lubricates the deceleration device  2  can be directly placed in the deceleration device  2 . 
     For example, the turbine fracturing apparatus may be also provided with an air inlet system and an air exhaust system of the turbine engine. 
     As illustrated in  FIG.  10 A , the plunger pump  3  may be connected with the turbine engine  1  through the deceleration device  2 . A coupling  55  may be provided between the plunger pump  3  and the deceleration device  2 . One end of the turbine engine  1  may be connected with the plunger pump  3  through the deceleration device, so as to drive the plunger pump to draw/intake low-pressure fracturing fluid and discharge high-pressure fracturing fluid. In other words, the plunger pump  3  may be configured to pressurize the fracturing fluid to form high-pressure fracturing fluid. As illustrated in  FIG.  10 A , the other end of the turbine engine  1  may be connected with an air exhaust assembly  49 , and the air exhaust assembly  49  may include an exhaust pipe  9  and a muffler  33 . The exhaust pipe  9  may be connected with the turbine engine  1  and configured to discharge the exhaust gas. The muffler  33  may be connected with the exhaust pipe  9  and configured to reduce exhaust noise. The fuel tank  02  may supply oil to the engine  03 . The engine  03  may be connected with a hydraulic pump  04  (not illustrated in  FIG.  10 A , referring to  FIG.  10 B ), and the hydraulic tank  01  may be connected with the hydraulic pump  04  (referring to  FIG.  10 B ). 
       FIG.  10 A  illustrates an example muffling compartment  71 . As illustrated in  FIG.  10 A , the turbine engine  1  and the deceleration device  2  may be located in the muffling compartment  71 , and the muffling compartment  71  may be configured to reduce noise.  FIG.  10 A  further illustrates an example high-pressure manifold  112 . For example, the high-pressure manifold  112  may be configured to allow high-pressure fracturing fluid to flow therein. The high-pressure manifold  112  may include a discharge end  102 . 
     As illustrated in  FIG.  10 B , the hydraulic pump  04  may supply oil to an actuating motor  040  of the turbine fracturing apparatus. The actuating motor  04  may include a starting motor  041 , a lubricating motor  042 , a cooling motor  043 , an air supplying motor  044 , and a ventilating motor  045 . The lubricating motor  042  may be connected with the lubricating pump  11  to drive the lubricating pump  11  to deliver lubricating oil from the lubricating oil tank  81  to the plunger pump  3 , the deceleration device  2 , and the turbine engine  1  for lubrication. For example, the vehicle body  100  may include a semi-trailer, but is not limited thereto. The ventilating motor  045  may drive a ventilation component  14 . For example, the ventilation component may include a fan, but is not limited thereto. 
     As illustrated in  FIG.  10 B , the cooling motor  043  may drive the cooling component  32 . The starting motor  041  may be connected with the turbine engine  1  to start the turbine engine  1 , and the air supplying motor  044  may drive an air compressor  06 . For example, the cooling component  3  may include a fan, but is not limited thereto. 
     According to the turbine fracturing apparatus provided by the example embodiment of the present disclosure, the auxiliary power unit  4  may include at least one selected from the group consisting of a starting unit  401 , a lubricating unit  402 , a cooling unit  403 , an air supplying unit  404  and a ventilating unit  405 . The auxiliary motor may include at least one of a starting motor  041 , a lubricating motor  042 , a cooling motor  043 , an air supplying motor  044 , or a ventilating motor  045 .  FIG.  10 C  is a schematic diagram illustrating that the lubricating motor  042  may be driven by the deceleration device  2 . In some other embodiments, the lubricating motor  042  can be driven by the turbine engine  1 . Accordingly, at least one of the cooling motor  043 , the air supplying motor  044 , or the ventilating motor  045  can be installed on the turbine engine  1  or the deceleration device  2 , so as to be driven by the turbine engine  1  or the deceleration device  2 . That is, in the embodiment of the present disclosure, at least one of the lubricating motor  042 , the cooling motor  043 , the air supplying motor  044 , or the ventilating motor  045  can be driven by the turbine engine  1  or the deceleration device  2 . 
     For example, the output end  22  of the deceleration device  2  can also be connected with other auxiliary power components, such as motors, pumps, etc. 
     For example, the auxiliary power unit  4  may include the lubrication system, the hydraulic system, the air supply system and the heat dissipation system of the whole apparatus. The whole apparatus may be equipped with a noise reduction device to reduce the noise of the apparatus. The noise reduction device may help realize noise reduction for the turbine engine  1 , the deceleration device  2 , the plunger pump  3  and other noise sources. 
     The starting motor  041 , the lubricating motor  042 , the cooling motor  043 , the air supplying motor  044 , and the ventilating motor  045  in the turbine fracturing apparatus illustrated in  FIG.  10 A  and  FIG.  10 B  may be hydraulically driven. However, at least one of the starting motor  041 , the lubricating motor  042 , the cooling motor  043 , the air supplying motor  044 , and the ventilating motor  045  can instead be installed on the turbine engine  1  or the deceleration device  2 , and driven by the turbine engine  1  or the deceleration device  2 , instead of being hydraulically driven. 
     For example, the manner of hydraulically driving the auxiliary power unit illustrated in  FIG.  10 A  and  FIG.  10 B  can also be replaced by electric driving. Therefore, alternative to the auxiliary motor being directly driven by the turbine engine  1  or the deceleration device  2 , one or more auxiliary motors in the auxiliary power unit can be electrically driven. 
     The embodiment of the present disclosure is illustrated by implementing a single turbine engine and double pumps. In the case where one turbine engine corresponds to three or more plunger pumps, multiple plunger pumps can be sequentially arranged at the side of the deceleration device  2  along the long edge of the deceleration device  2 . Multiple plunger pumps can also be divided into two groups, and these two groups of plunger pumps may be arranged at the two long edges of the deceleration device  2 . In other words, plunger pumps of each group may be sequentially arranged at the side of the deceleration device  2  along the long edge of the deceleration device  2 . 
     For example, in some embodiments of the present disclosure, the plurality of plunger pumps can be dispersedly distributed. For example, the plurality of plunger pumps may not be arranged in the same width direction, and/or the plurality of plunger pumps may not be arranged in the same length direction. For example, the direction X mat be the length direction, and the direction Y may be the width direction. 
     The embodiment of the present disclosure further provides a turbine fracturing well site, which includes any one of the turbine fracturing apparatuses mentioned above and belonging to the field of petroleum equipment 
       FIG.  11    is a schematic diagram of an example turbine fracturing well site provided by an embodiment of the present disclosure. As illustrated in  FIG.  11   , the turbine fracturing well site  200  may further include a manifold skid  20 . Each plunger pump  3  may include a discharge end  102 . The discharge end  102  of the plunger pump  3  may be configured to discharge high-pressure fluid, and the discharge ends  32  of two plunger pumps  3  may be arranged towards the manifold skid  20 . 
       FIG.  11    further illustrates a suction end  101  of the turbine fracturing apparatus  10 . The suction end  101  may be configured to draw/suck/intake low-pressure fluid. The suction end  101  may be the end of the plunger pump that draws/sucks/intakes low-pressure fluid. 
     As illustrated in  FIG.  11   , each turbine fracturing apparatus  10  may have two suction ends  101  and two discharge ends  102 . That is, each plunger pump has a suction end  101  and a discharge end  102 . 
     A plurality of turbine fracturing apparatuses  10  may form a turbine fracturing set.  FIG.  11    is described with reference to the case where the turbine fracturing set includes four turbine fracturing apparatuses  10 , by way of example. 
       FIG.  11    further illustrates a low-pressure manifold  121  and a high-pressure manifold  122 . As illustrated in  FIG.  11   , the low-pressure manifold  121  may include two branches to be connected with the suction ends  101  of two plunger pumps, respectively, in one turbine fracturing apparatus  10 . 
       FIG.  11    illustrates the natural gas pipeline layout of a well site containing the fracturing apparatus provided by the embodiment of the present disclosure.  FIG.  11    further illustrates a gas pipeline  30 . For example, the gas pipeline  30  is configured to supply gas to the turbine engine  1 . 
     As illustrated in  FIG.  11   , compared with the common well site, the arrangement manner is changed. The well site layout is more compact. 
     For example, in some embodiments of the present disclosure, one turbine engine corresponds to two high-pressure output manifolds. 
     For example, the end of the plunger pump  3  facing away from the deceleration device  2  may be the discharge end. 
     The turbine fracturing apparatuses illustrated in  FIG.  1   - FIG.  6    are described with reference to the case where the left side is the front end of the vehicle, the right side is the rear end of the vehicle, and the side surface of the vehicle is between the front end and the rear end, by way of example. In the turbine fracturing apparatus illustrated in  FIG.  1    and  FIG.  4   , the side surface of the vehicle faces the manifold skid  20 . In the turbine fracturing apparatus illustrated in  FIG.  2    and  FIG.  5   , the rear end of the vehicle faces the manifold skid  20 . In the turbine fracturing apparatus illustrated in  FIG.  3    and  FIG.  6   , the side surface of the vehicle faces the manifold skid  20 . 
     What have been described above are only specific example implementations of the present disclosure, and the protection scope of the present disclosure is not limited thereto. Any changes or substitutions readily derivable by those having ordinary skill in the art according to this disclosure and within the technical scope of the present disclosure should be covered in the protection scope of the present disclosure. The protection scope of the present disclosure should be determined at least based on the protection scope of the claims.