Double chamber religious rotary live cattle slaughter box
The design of the dual-chamber religious rotating live cattle slaughter box solves the problem of low efficiency of the single-chamber rotating slaughter box, realizes dual-chamber continuous slaughter, improves slaughter efficiency and device feasibility, adapts to the compression and fixation of cattle of different sizes, and ensures that the cattle slide out smoothly through the hydraulic flip-up cattle receiving frame.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANDONG HUAYU MACHINERY EQUIP
- Filing Date
- 2025-07-07
- Publication Date
- 2026-06-23
Smart Images

Figure CN224386617U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a dual-cavity religious rotating live cattle slaughtering box, belonging to the field of live cattle slaughtering devices. Background Technology
[0002] Currently, halal-style live cattle slaughter mainly uses a single-chamber rotary slaughter box. Because it involves a series of operations such as herding the cattle, fixing the carcass, rotating, stabbing, and draining blood, its efficiency is relatively low. Most slaughtering production lines require a large overall investment, but the slaughtering process limits the improvement of overall efficiency. Furthermore, although the concept of a dual-chamber circulation system was proposed many years ago, due to technical limitations, no practically usable models have appeared on the market. Summary of the Invention
[0003] Based on the problems described in the background, the problem to be solved by this utility model is to provide a dual-cavity religious rotating live cattle slaughtering box. The dual-cavity mechanism is formed by using two mature cavity mechanisms of single-cavity rotating slaughtering boxes, which are connected to a large-diameter split drive wheel and a front end plate to form a whole. A central positioning round tube is provided in the middle, and the front and rear support shafts at both ends are connected. The front and rear support shafts are fixed to the front and rear support seats through bearing seats, thereby realizing the continuous rotation of the dual cavities and solving the problems of low efficiency and inability to be truly put into use mentioned above.
[0004] To achieve the above objectives, this utility model provides the following technical solution: a dual-cavity religious rotating live cattle slaughter box, including a drive assembly, a dual-cavity rotating mechanism, a cattle positioning assembly, a front support assembly, a rear support assembly, a cattle entry gate assembly, a cattle receiving pen assembly, and a slaughtering platform. The dual-cavity rotating mechanism is a dual-cavity centrally symmetrical structure. The front and rear ends of the dual-cavity rotating mechanism are respectively equipped with a front support assembly and a rear support assembly, which are concentric. The drive assembly is installed on the rear support assembly. The cattle positioning assembly is installed in both cavities of the dual-cavity rotating mechanism. The cattle entry gate assembly is located at the entrance of one set of cavities of the dual-cavity rotating mechanism and is located on one side of the rear support assembly. A cattle receiving pen assembly is provided on one side of the dual-cavity rotating mechanism. A slaughtering platform is also provided at one end of the front support assembly of the dual-cavity rotating mechanism.
[0005] Preferably, the drive assembly includes a drive motor, a drive sprocket, a drive chain, an upper split drive wheel, a middle split drive wheel, a lower split drive wheel, and cattle inlets. The drive motor is mounted on the rear support assembly, and the output end of the drive motor is connected to the drive sprocket. The drive sprocket is connected to the drive chain. The upper split drive wheel, the middle split drive wheel, and the lower split drive wheel are bolted together to form a split drive wheel. The split drive wheel is connected to the drive chain. The split drive wheel is located at the rear end of the dual-cavity rotating mechanism. The middle split drive wheel has two sets of cattle inlets located at the entrances of the two sets of positioning cattle assemblies and is centrally symmetrical.
[0006] Preferably, the dual-cavity rotating mechanism includes a cavity frame, a front end plate, and a central positioning tube. The cavity frame is mounted on the split drive wheel of the drive assembly. The front end plate is mounted on the end of the cavity frame away from the drive assembly, and the central positioning tube is mounted at the center of the cavity frame.
[0007] Preferably, the cattle positioning assembly includes a neck clamp device, a jaw-top device, a cattle-driving pusher device, a hydraulically pressed outer pusher device, a hydraulically pressed inner pusher device, and a back-pressing device. The neck clamp device is mounted on the front end plate of the dual-cavity rotating mechanism. The jaw-top device is mounted above the neck clamp device and also on the front end plate. The cattle-driving pusher device is mounted on the cavity frame of the dual-cavity rotating mechanism and located at the end away from the front end plate. The hydraulically pressed outer pusher device is mounted on the outside of a single cavity of the dual-cavity rotating mechanism. The hydraulically pressed inner pusher device is mounted on the inside of a single cavity of the dual-cavity rotating mechanism. The back-pressing device is mounted on the cavity frame of the dual-cavity rotating mechanism. The neck clamp device, jaw-top device, cattle-driving pusher device, hydraulically pressed outer pusher device, hydraulically pressed inner pusher device, and back-pressing device are all installed in conjunction with the dual cavities of the dual-cavity rotating mechanism.
[0008] Preferably, the front support assembly includes a front support seat, a front bearing seat, and a front support shaft. The front support seat is located outside the front end plate of the dual-cavity rotating mechanism, and the front bearing seat is mounted on the front support seat. The front support shaft is installed in the central positioning tube of the dual-cavity rotating mechanism by cooperating with the front bearing seat.
[0009] Preferably, the rear support assembly includes a rear support seat, a rear bearing seat, and a rear support shaft. The rear support seat is located at the other end of the drive assembly, the rear bearing seat is mounted on the rear support seat, and the rear support shaft is mounted in the central positioning tube of the dual-cavity rotating mechanism by cooperating with the rear bearing seat.
[0010] Preferably, the cattle entry gate assembly includes a cattle entry gate frame, a cattle entry gate cylinder, and a cattle entry gate. The cattle entry gate frame is located on one side of the rear support assembly and at the entrance of a set of cattle positioning assemblies. The cattle entry gate cylinder is installed on the cattle entry gate frame, and the cattle entry gate is installed in the middle of the cattle entry gate frame. The cattle entry gate cylinder is connected to the cattle entry gate.
[0011] Preferably, the cattle receiving pen assembly includes a cattle receiving pen base frame, a fixed cattle receiving pen, a tilting cylinder, and a movable cattle receiving pen. The cattle receiving pen base frame is located on one side of the double-cavity rotating mechanism. The fixed cattle receiving pen, the tilting cylinder, and the movable cattle receiving pen are installed on the cattle receiving pen base frame. The output end of the tilting cylinder is connected to the movable cattle receiving pen. The fixed cattle receiving pen and the tilted movable cattle receiving pen are connected as a whole.
[0012] The beneficial effects of this utility model are:
[0013] 1. By connecting the mature mechanisms of two single-chamber slaughtering boxes through a rotating frame with a central positioning hook, a dual-chamber continuous slaughtering method is formed, which greatly improves slaughtering efficiency.
[0014] 2. This utility model adopts an integrated structure of a rear-end split drive wheel and a double-cavity rotating mechanism, which greatly improves the feasibility of the mechanism and simplifies transportation and installation with the large-diameter split drive wheel.
[0015] 3. The entire rotation is achieved using a single motor, ensuring stable control. The drive wheel is designed as a split structure for easy assembly.
[0016] 4. This device has clamping devices on both the inner and outer sides, which can clamp the cattle and can adapt to cattle of different sizes, and the operation is stable.
[0017] 5. The cattle receiving frame with a hydraulically tilting double-section structure allows the cattle to slide smoothly out of the positioning cavity after being stabbed, making this utility model more feasible. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the structure of this utility model;
[0019] Figure 2 This is a schematic diagram of the structure of this utility model;
[0020] Figure 3 for Figure 2 A sectional view;
[0021] Figure 4 This is a side view of the present invention;
[0022] Figure 5 This is a rear view of the present invention;
[0023] Figure 6 This is a top view of the present invention;
[0024] Figure 7 This is a partial schematic diagram of a dual-cavity rotating mechanism;
[0025] In the diagram: 1 is the drive assembly; 2 is the dual-cavity rotating mechanism; 3 is the cattle positioning assembly; 4 is the front support assembly; 5 is the rear support assembly; 6 is the cattle entry gate assembly; 7 is the cattle receiving pen assembly; 8 is the slaughtering platform; 11 is the drive motor; 12 is the drive sprocket; 13 is the drive chain; 14 is the upper split drive wheel; 15 is the middle split drive wheel; 16 is the lower split drive wheel; 17 is the cattle inlet; 21 is the cavity frame; 22 is the front end plate; 23 is the central positioning tube; 31 is the neck clamp device. ; 32 is the top jaw device; 33 is the cattle-driving push plate device; 34 is the hydraulic pressing outer push plate device; 35 is the hydraulic pressing inner push plate device; 36 is the back pressing device; 41 is the front support seat; 42 is the front bearing seat; 43 is the front support shaft; 51 is the rear support seat; 52 is the rear bearing seat; 53 is the rear support shaft; 61 is the cattle-entry gate frame; 62 is the cattle-entry gate cylinder; 63 is the cattle-entry gate; 71 is the cattle-receiving pen base frame; 72 is the fixed cattle-receiving pen; 73 is the tilting cylinder; 74 is the movable cattle-receiving pen. Detailed Implementation
[0026] The embodiments of this utility model will be further described below with reference to the accompanying drawings:
[0027] Example 1
[0028] like Figures 1-7 As shown, this utility model provides a dual-cavity religious rotating live cattle slaughter box, including a drive assembly 1, a dual-cavity rotating mechanism 2, a cattle positioning assembly 3, a front support assembly 4, a rear support assembly 5, a cattle entry gate assembly 6, a cattle receiving pen assembly 7, and a slaughtering platform 8. The dual-cavity rotating mechanism 2 has a dual-cavity centrally symmetrical structure. The front support assembly 4 and the rear support assembly 5 are respectively installed at the front and rear ends of the dual-cavity rotating mechanism 2. The front support assembly 4 and the rear support assembly 5 are concentric. The drive assembly 1 is installed on the rear support assembly 5. The cattle positioning assembly 3 is installed in both cavities of the dual-cavity rotating mechanism 2. The cattle entry gate assembly 6 is located at the entrance of one set of cavities of the dual-cavity rotating mechanism 2 and is located on one side of the rear support assembly 5. The cattle receiving pen assembly 7 is provided on one side of the dual-cavity rotating mechanism 2. The slaughtering platform 8 is also provided at one end of the front support assembly 4 of the dual-cavity rotating mechanism 2.
[0029] like Figure 2 and Figure 3As shown, the drive assembly 1 includes a drive motor 11, a drive sprocket 12, a drive chain 13, a split drive wheel upper 14, a split drive wheel middle 15, a split drive wheel lower 16, and a cattle inlet 17. The drive motor 11 is mounted on the rear support assembly 5. The output end of the drive motor 11 is connected to the drive sprocket 12. The drive sprocket 12 is connected to the drive chain 13. The split drive wheel upper 14, the split drive wheel middle 15, and the split drive wheel lower 16 are bolted together to form a split drive wheel. The split drive wheel is connected to the drive chain 13. The split drive wheel is located at the rear end of the double-cavity rotating mechanism 2. The split drive wheel middle 15 has two sets of cattle inlets 17, which are located at the entrances of the two sets of positioning cattle assemblies 3 and are centrally symmetrical.
[0030] The split drive wheels are assembled by splicing together, which not only enables driving but also facilitates installation, and simplifies transportation and installation.
[0031] like Figure 7 As shown, the dual-cavity rotating mechanism 2 includes a cavity frame 21, a front end plate 22, and a central positioning tube 23. The cavity frame 21 is mounted on the split drive wheel 15 of the drive assembly 1. The front end plate 22 is mounted at the end of the cavity frame 21 away from the drive assembly 1, and the central positioning tube 23 is mounted at the center of the cavity frame 21.
[0032] The dual-cavity rotating mechanism 2 is constructed by two mature cavity mechanisms of single-cavity rotating slaughter boxes to form a dual-cavity pattern. At the same time, the central positioning tube 23 at the center position is convenient to connect with the front support component 4 and the rear support component 5, and also ensures that the entire rear support is concentric. It is connected to the split drive wheel of the drive component 1 to form continuous rotation of the dual cavities.
[0033] like Figure 2 and Figure 3 As shown, the cattle positioning assembly 3 includes a neck clamp device 31, a jaw-top device 32, a cattle-driving pusher device 33, a hydraulically pressed outer pusher device 34, a hydraulically pressed inner pusher device 35, and a back-pressing device 36. The neck clamp device 31 is mounted on the front end plate 22 of the dual-cavity rotating mechanism 2. The jaw-top device 32 is mounted above the neck clamp device 31 and also on the front end plate 22. The cattle-driving pusher device 33 is mounted on the cavity frame 21 of the dual-cavity rotating mechanism 2 and is located away from the front end plate 22. At one end, the hydraulic pressing outer push plate device 34 is installed on the outside of the single cavity of the double cavity rotating mechanism 2, the hydraulic pressing inner push plate device 35 is installed on the inside of the single cavity of the double cavity rotating mechanism 2, and the back pressing device 36 is installed on the cavity frame 21 of the double cavity rotating mechanism 2. The neck clamp device 31, the top jaw device 32, the cattle driving push plate device 33, the hydraulic pressing outer push plate device 34, the hydraulic pressing inner push plate device 35, and the back pressing device 36 are all installed in conjunction with the double cavity of the double cavity rotating mechanism 2.
[0034] After the cattle enter, the cattle are driven to the front position by the cattle pushing plate device 33. At this time, the hydraulic pressing outer pushing plate device 34, the hydraulic pressing inner pushing plate device 35 and the back pressing device 36 are operated. The hydraulic pressing outer pushing plate device 34 and the hydraulic pressing inner pushing plate device 35 press the cattle inward, and the back pressing device 36 presses the cattle down to fix the cattle. Then, the neck clamp device 31 fixes the neck of the cattle and the jaw clamp device 32 fixes the head of the cattle to fix the cattle completely.
[0035] This device has clamping devices on both the inside and outside, which can clamp the cattle and can adapt to cattle of different sizes. It operates stably.
[0036] like Figure 2 , Figure 4 and Figure 6 As shown, the front support assembly 4 includes a front support seat 41, a front bearing seat 42, and a front support shaft 43. The front support seat 41 is located outside the front end plate 22 of the dual-cavity rotating mechanism 2. The front bearing seat 42 is mounted on the front support seat 41. The front support shaft 43 is installed in the central positioning tube 23 of the dual-cavity rotating mechanism 2 by cooperating with the front bearing seat 42.
[0037] like Figure 4 , Figure 5 and Figure 6 As shown, the rear support assembly 5 includes a rear support seat 51, a rear bearing seat 52, and a rear support shaft 53. The rear support seat 51 is located at the other end of the drive assembly 1. The rear bearing seat 52 is mounted on the rear support seat 51. The rear support shaft 53 is installed in the central positioning tube 23 of the dual-cavity rotating mechanism 2 by cooperating with the rear bearing seat 52.
[0038] The front support shaft 43 and the rear support shaft 53 of the front support assembly 4 and the rear support assembly 5 are connected and fixed by the central positioning tube 23 to form a rotating shaft. The front and rear ends are separated for easy transportation.
[0039] like Figure 4 and Figure 5 As shown, the cattle entry gate assembly 6 includes a cattle entry gate frame 61, a cattle entry gate cylinder 62, and a cattle entry gate 63. The cattle entry gate frame 61 is located on one side of the rear support assembly 5 and at the entrance of a set of cattle positioning assemblies 3. The cattle entry gate cylinder 62 is installed on the cattle entry gate frame 61, and the cattle entry gate 63 is installed in the middle of the cattle entry gate frame 61. The cattle entry gate cylinder 62 is connected to the cattle entry gate 63.
[0040] Before the cattle enter, the cattle entry gate 63 is opened. After the cattle enter, the cattle entry gate cylinder 62 is activated, which drives the cattle entry gate 63 to fall, completing the cattle entry operation.
[0041] like Figure 2 and Figure 3As shown, the cattle receiving pen assembly 7 includes a cattle receiving pen base frame 71, a fixed cattle receiving pen 72, a tilting cylinder 73, and a movable cattle receiving pen 74. The cattle receiving pen base frame 71 is located on one side of the double-cavity rotating mechanism 2. The fixed cattle receiving pen 72, the tilting cylinder 73, and the movable cattle receiving pen 74 are installed on the cattle receiving pen base frame 71. The output end of the tilting cylinder 73 is connected to the movable cattle receiving pen 74. The fixed cattle receiving pen 72 and the tilted movable cattle receiving pen 74 are connected as a whole.
[0042] After the cattle are slaughtered, the lifting cylinder 73 lowers the movable cattle receiving pen 74, and all the components of the positioning cattle assembly 3 are released. The slaughtered and bled cattle carcass falls naturally, first into the movable cattle receiving pen 74, and then the movable cattle receiving pen 74 is lifted and enters the fixed cattle receiving pen 72. At the same time, the lifted movable cattle receiving pen 74 isolates the cattle from the cavity, preventing damage to the equipment from kicking.
[0043] Workflow:
[0044] 1. When the cattle inlet gate 63 is opened, the cattle enter one cavity of the cavity frame 21 through the cattle inlet 17. The cattle gate cylinder 62 is activated, which causes the cattle inlet gate 63 to fall and close.
[0045] 2. The positioning cattle component 3 for entering the cattle cavity is activated. The cattle is driven to the front position by the cattle pushing plate device 33. At this time, the hydraulic pressing outer pushing plate device 34, the hydraulic pressing inner pushing plate device 35 and the back pressing device 36 are activated. The hydraulic pressing outer pushing plate device 34 and the hydraulic pressing inner pushing plate device 35 press the cattle inward, and the back pressing device 36 presses the cattle down to fix the cattle. Then, the neck clamp device 31 fixes the neck of the cattle, and the top jaw device 32 fixes the head of the cattle, thus fixing the cattle completely.
[0046] 3. When the drive component 1 is activated, the drive motor 11 drives the drive sprocket 12 to rotate, the drive sprocket 12 drives the drive chain 13 to move, and the drive chain 13 drives the split drive wheel to rotate, causing the double-cavity rotating mechanism 2 to rotate 180°, and the movable cattle pen 74 flips up in advance during the rotation.
[0047] 4. The operator stands on the stabbing platform 8 to stab and bleed the cattle. At the same time, the cattle entry gate 63 is opened, and the cattle enter another cavity of the cavity frame 21 through the cattle entry port 17. The cattle gate cylinder 62 is activated, which drives the cattle entry gate 63 to fall and close, completing the cattle entry operation in the other cavity.
[0048] 5. While the cow in the first cavity is being stabbed and bled, the movable cow receiving pen 74 falls down, all the components of the cow positioning component 3 are released, and the slaughtered and bled cow carcass naturally slides into the cow receiving pen component 7.
[0049] 6. Then the cattle pen 74 is flipped up again to isolate the cattle from the cavity and prevent them from kicking and damaging the equipment. The drive component 1 drives the double cavity rotating mechanism 2 to rotate 180° again to start the next cycle.
Claims
1. A dual chamber religious rotary live cattle slaughter box characterized in that, The device includes a drive assembly (1), a double-cavity rotating mechanism (2), a cattle positioning assembly (3), a front support assembly (4), a rear support assembly (5), a cattle entry gate assembly (6), a cattle receiving pen assembly (7), and a killing platform (8). The double-cavity rotating mechanism (2) is a double-cavity centrally symmetrical structure. The front and rear ends of the double-cavity rotating mechanism (2) are respectively equipped with a front support assembly (4) and a rear support assembly (5). The front support assembly (4) and the rear support assembly (5) are concentric. The drive assembly (1) is installed on the rear support assembly (5). The cattle positioning assembly (3) is installed in both cavities of the double-cavity rotating mechanism (2). The cattle entry gate assembly (6) is located at the entrance of one set of cavities of the double-cavity rotating mechanism (2) and is located on one side of the rear support assembly (5). The cattle receiving pen assembly (7) is provided on one side of the double-cavity rotating mechanism (2). The killing platform (8) is also provided at one end of the front support assembly (4) of the double-cavity rotating mechanism (2).
2. A double chambered religious rotary live cattle slaughter box according to claim 1, characterized in that, The drive assembly (1) includes a drive motor (11), a drive sprocket (12), a drive chain (13), a split drive wheel upper (14), a split drive wheel middle (15), a split drive wheel lower (16), and a cattle inlet (17). The drive motor (11) is mounted on the rear support assembly (5). The output end of the drive motor (11) is connected to the drive sprocket (12). The drive sprocket (12) is connected to the drive chain (13). The split drive wheel upper (14), the split drive wheel middle (15), and the split drive wheel lower (16) are bolted together to form a split drive wheel. The split drive wheel is connected to the drive chain (13). The split drive wheel is located at the rear end of the double-cavity rotating mechanism (2). Two sets of cattle inlets (17) are provided on the split drive wheel middle (15) and are symmetrical.
3. A double chambered religious rotary live cattle slaughter box according to claim 1, characterized in that, The dual-cavity rotating mechanism (2) includes a cavity frame (21), a front end plate (22), and a central positioning tube (23). The cavity frame (21) is mounted on the split drive wheel (15) of the drive assembly (1). The front end plate (22) is mounted on the end of the cavity frame (21) away from the drive assembly (1), and the central positioning tube (23) is mounted at the center of the cavity frame (21).
4. A double chambered religious rotary live cattle slaughter box according to claim 1, characterized in that, The cattle positioning assembly (3) includes a neck clamp device (31), a jaw-top device (32), a cattle-driving pusher device (33), a hydraulically pressed outer pusher device (34), a hydraulically pressed inner pusher device (35), and a back-pressing device (36). The neck clamp device (31) is mounted on the front end plate (22) of the double-cavity rotating mechanism (2). The jaw-top device (32) is mounted above the neck clamp device (31) and also on the front end plate (22). The cattle-driving pusher device (33) is mounted on the cavity frame (21) of the double-cavity rotating mechanism (2) and is located away from the front end plate (22). At one end of the double-cavity rotating mechanism (2), the hydraulic pressing outer push plate device (34) is installed on the outside of the single cavity of the double-cavity rotating mechanism (2), the hydraulic pressing inner push plate device (35) is installed on the inside of the single cavity of the double-cavity rotating mechanism (2), and the back pressing device (36) is installed on the cavity frame (21) of the double-cavity rotating mechanism (2). The neck clamp device (31), the top jaw device (32), the cattle driving push plate device (33), the hydraulic pressing outer push plate device (34), the hydraulic pressing inner push plate device (35) and the back pressing device (36) are all installed in conjunction with the double cavity of the double-cavity rotating mechanism (2).
5. A double chambered religious rotary live cattle slaughter box according to claim 1, characterized in that, The front support assembly (4) includes a front support seat (41), a front bearing seat (42), and a front support shaft (43). The front support seat (41) is located outside the front end plate (22) of the dual-cavity rotating mechanism (2). The front bearing seat (42) is mounted on the front support seat (41). The front support shaft (43) is installed in the central positioning tube (23) of the dual-cavity rotating mechanism (2) by cooperating with the front bearing seat (42).
6. A double chambered religious rotary live cattle slaughter box according to claim 1, characterized in that, The rear support assembly (5) includes a rear support seat (51), a rear bearing seat (52), and a rear support shaft (53). The rear support seat (51) is located at the other end of the drive assembly (1). The rear bearing seat (52) is mounted on the rear support seat (51). The rear support shaft (53) is installed in the central positioning tube (23) of the dual-cavity rotating mechanism (2) by cooperating with the rear bearing seat (52).
7. A double chambered religious rotary live cattle slaughter box according to claim 1, characterized in that, The cattle entry gate assembly (6) includes a cattle entry gate frame (61), a cattle entry gate cylinder (62), and a cattle entry gate (63). The cattle entry gate frame (61) is located on one side of the rear support assembly (5) and at the entrance of a set of cattle positioning assemblies (3). The cattle entry gate cylinder (62) is installed on the cattle entry gate frame (61), and the cattle entry gate (63) is installed in the middle of the cattle entry gate frame (61). The cattle entry gate cylinder (62) is connected to the cattle entry gate (63).
8. The dual-cavity religious rotating live cattle slaughtering box according to claim 1, characterized in that, The cattle receiving pen assembly (7) includes a cattle receiving pen base frame (71), a fixed cattle receiving pen (72), a tilting cylinder (73), and a movable cattle receiving pen (74). The cattle receiving pen base frame (71) is located on one side of the double-cavity rotating mechanism (2). The fixed cattle receiving pen (72), the tilting cylinder (73), and the movable cattle receiving pen (74) are installed on the cattle receiving pen base frame (71). The output end of the tilting cylinder (73) is connected to the movable cattle receiving pen (74). The fixed cattle receiving pen (72) and the tilted movable cattle receiving pen (74) are connected as a whole.